NO328703B1 - Method and apparatus for producing energy - Google Patents

Abstract

A method of producing energy from a stream of water is described, in which a rotating means rotates or rotates and drives a generator for producing said energy, and the method is characterized in that through a connection (104) arranged through a land mass (S) defining a separation between two sea areas (A, B) with different tidal cycles, a water flow is generated due to the different levels between the two sea areas (A, B), and said rotating means is arranged in the water flow to produce said energy.

Description

The present invention relates to a method for producing energy from a stream of water, in which a rotary device rotates or turns and drives a generator for producing said energy. The invention also relates to a plant for the production of energy. Furthermore, the invention relates to an application of said facility.

Introduction.

Use of energy is increasing strongly both nationally and globally. Continued growth in the production of energy is an important factor for the further economic development of the world community. At the same time, the threat from climate change with global warming as a result has become a unified reality. It is therefore particularly important to increase the percentage of renewable energy in total energy consumption.

With the present invention, the purpose is to be able to utilize a new source for the production of renewable electrical energy. The world's oceans represent enormous amounts of energy. It is well known to utilize existing tidal and ocean currents for power generation by arranging water wheels, water turbines and the like directly in a tidal current that pulsates back and forth, and in many varying ways.

The present invention has a completely different starting point, as it aims to utilize the power potential in the tidal wave that propagates around the globe in a way that has not previously been proposed: When the tidal wave meets land formations, permanent time shifts in the tidal wave and/or permanent changes in the tidal pattern occur. Such permanent changes in the water bodies' vertical movement pattern can be utilized for power production by a technically constructed horizontal connection through the land mass between these water bodies.

It is an ancient knowledge that moving water can be used to perform mechanical work. The principle is that water from an elevation is led via a channel or pipe to a paddle wheel at a lower elevation. There are many variations of the principle, but the basis is always the same; the force of gravity drives the impeller by setting the water in motion. The movement of the paddle wheel is then transferred via the shaft to drive mills, machines, or as is common nowadays: to drive turbines with a generator that produces electricity. The first use of water-powered paddle wheels took place in India 400 BC. The innovation spread and was established in the Greco-Roman cultural area as early as 100 BC.

Paddle wheels powered by tides have a shorter history. The oldest principle is an indirect exploitation of the tide. A dike with a sluice gate is established in the tidal water zone. When it flows, the water flows into the dike via the lock. The lock gate closes automatically when the tide turns. When the water difference is large enough, the stored water is released through a chute and this drives the paddle wheel. The oldest discovery of such tidal mills was made at Strangford Lough in Northern Ireland and dated to the year 787 AD.

The first paddle wheel driven directly by natural tidal flow was built in Bergen in 1599. At the tidal flow between the Lungegårdsvannen and the Puddefjord, the paddle wheel and mill were built on bulwarks. Bricklayers directed the tide into the water chute which drove the paddle wheel. The principle was so sensational that the Danish-Norwegian king Christian IV traveled from Copenhagen to Bergen in the same year to study the facility.

In relation to this historical context, the present invention aims to use paddle wheels in a water channel to operate power generators. With the present invention, this age-old principle is put into a completely new and epoch-making context.

Modern tidal power plants also build on the principles from the two main historical types described above: • Tidal turbines are lowered into natural ocean currents/tidal currents and the system utilizes the kinetic energy from moving water to drive power turbines in the same way that modern windmills utilize wind (Hammer-fest, 2002). • Damping captures the potential energy in the height difference between high and low tide. The stored water is passed through turbines. Example of this

the type of tidal power plant is La Ranch (1966) in France.

The present invention has nothing in common with the two above-mentioned systems. Instead, the aim is to create new, artificial, tidal currents in water channels inside tunnels or tunnels/pipes. These artificial water flows will be calculable and controllable, and the water channels can be used in their entire length and, for example, maintained on dry land in the mountains.

Prior art.

Regarding the state of the art, reference should be made on this occasion to Japanese publication JP-2000018146, British patent GB-2298004, French patents FR-2309671 and FR-1337074 as well as US patent document US2003/0192308

Below, some of these publications will be reviewed in a little more detail.

The Japanese publication JP2000018146 has as its starting point that tides should be brought into a low-lying sea and then back out again, and in particular both on the Mexican east coast and on the Mexican west coast. It is possible - even proposed - to connect a low-lying sea in southern Mexico to both the Pacific Ocean and the Gulf of Mexico. Water from the tide in the Pacific Ocean can then be stored there and released at low tide (spring) in the Gulf of Mexico.

British patent publication GB-2298004 is based on a very specific location on the Orkney Islands, the Churchill barrier, an artificial barrier built as a defence. There is a different tidal pattern on each side of the barrier. This is to be utilized by building a turbine. The patent mentions other artificial barriers in the area where this can also be done. It is also mentioned that this can be done at a naturally narrow headland. It is possible to produce electrical energy using the patent GB2298004 at these locations. In reality, this plant only utilizes a blocked clean tidal flow.

The technical solution referred to in US patent application 2003/0192308 is to be used in connection with a relatively large bay with a large body of water, which is partially separated from the sea/ocean by natural land masses, as is often the case at the entrance to a larger bay . In such a situation, one water area will, due to the tidal effect, have higher water pressure than the other area at certain times in a normal daily cycle. Consequently, there is a time delay in the equalization of the water levels inside the bay and outside, and it takes some time before the level difference is equalized, which means that the water flow that occurs through the passage into and out of the bay can be utilized by building a turbine plant. According to this publication, it is further stated that the barrier should have a sufficient length to induce a time delay in the equalization of said water levels as the tide falls and rises. It is stated that a length of 1 kilometer is preferred. US-2003/0192308 consequently has a completely different phenomenological and theoretical starting point than the one aimed at using in the present patent application.

With the present invention, the aim is to exploit the natural phenomenon that land masses and/or topography on the seabed can cause a time shift in an otherwise identical tidal pattern. This phase shift causes permanent differences in the tidal rhythm of the sea areas on either side of the said land mass. There is therefore no equalization of the water masses as mentioned in the above-mentioned US patent. On the contrary, the sine curves of the tides on either side of the land masses are permanently offset from each other, intersecting for a brief moment while one body of water is still ebbing and the other ebbing.

In the present patent application, the aim is therefore to utilize the permanent cyclical level differences for artificial tidal currents as a result of a wave-decelerating landmass. This tidal flow will not reverse at mathematical high/low tide, but will have a rapid turning point at the time the two sine curves intersect, as shown by an example in figure 3. • Land masses and/or topography on the seabed can result in a permanently different tidal pattern in the sea areas on either side of the land mass. Even with this natural phenomenon, there will be no "equalisation" of the water masses. On the contrary. Also in the case of such phenomena, the sine curves of the tide will be different on a permanent basis. An artificial tidal current will not reverse at mathematical ebb and flow, but when the sine curves cross each other. It has been shown that there are significant differences from locality to locality, but the inequalities at each locality will always be permanent. At a few localities, an artificial tidal current between two sea areas will always flow in one direction. In the present invention, one will utilize such permanent rhythm differences between sea levels for electrical production by creating a tunnel connection or tunnel/pipe connection between them, as shown in figures 9 and 10. • In US2003/0192308, a length of at least one kilometer is indicated as preferred. The present invention idea does not support such preferences or limitations. On the contrary. The present solution can be used in all places where natural conditions defacto create either permanent time differences in the same tidal rhythm, where natural conditions create a permanently different tidal pattern or where natural conditions create both permanent time differences in the tidal cycle and a permanently different tidal pattern. There will be financial assessments that determine whether or not the patent is to be used at a location.

The US application 2003/0192308 actually only deals with the drainage of

existing tidal currents.

The differences in technical solutions are obvious between the present invention and patent US2003/0192308.

Present invention.

The method according to the invention is characterized in that

it is produced through a channel connection arranged through a land mass which defines a separation between two sea areas with different tidal cycles, a water flow as a result of the different sea levels between the two sea areas, where the separation leads to a phase shift in the sea areas' tidal cycles, and said rotation device is arranged in the water flow for to produce said energy, as

an upwardly open channel is used whose upper level is located above the astronomical tide level of the two sea areas, the bottom level of the channel is lower than the mathematical tide level of the two sea areas.

According to a preferred embodiment, a connection in the form of a channel is used, the bottom of which is arranged at the same elevation throughout the length of the channel.

According to yet another preferred embodiment, a connection in the form of a channel is used through the land mass S at a distance below the two sea levels, the channel being defined at the same elevation throughout the length of the channel.

According to yet another preferred embodiment, a gutter is used which is internally covered with a material that provides the least possible friction against the water flow, which material is preferably metal sheets, plastic or other malleable and durable material.

According to yet another preferred embodiment, an inlet funnel is used to accumulate the volume of water into the channel, and that means are used to determine the amount of water and flow rate in the channel.

The plant according to the invention is characterized by

a channel arranged through a land mass which defines a separation between two sea areas with different tidal cycles, in order to establish a water flow as a result of the different sea levels between the two sea areas, where the separation leads to a phase shift in the sea areas' tidal cycles, and said rotary device is arranged to is arranged in the water flow to produce said energy, as

the channel's upper level is located above the astronomical tide level of the two sea areas, and the channel's bottom level is lower than the mathematical tide level of the two sea areas.

According to a preferred embodiment, the bottom of the channel connection is arranged at the same elevation throughout the entire length of the channel. Furthermore, the channel can be open upwards.

According to a preferred embodiment, the channel runs through the land mass (S) at a distance below the two sea levels, the channel being defined at the same elevation throughout the length of the channel. The channel is otherwise internally covered with a material that provides the least possible friction against the water flow, which material is preferably metal plates, plastic or other malleable and durable material.

Preferably, each end of the channel comprises a funnel-shaped zone to increase the in/out of water in the channel, and to determine the amount of water/flow rate in the water channel.

According to a preferred embodiment, each inflow comprises breakwaters and a blocking device for unwanted material, as well as possibly a sluice gate which can stop the water flow at any time.

Preferably, a number of water turbines are used which drive generators which produce electrical energy.

The channel can, according to yet another preferred embodiment, be arranged embedded in the floor of a tunnel which is unformed through the landmass. It can also be arranged as an artificial chute standing on the floor of a tunnel that is unformed through the landmass.

According to the invention, the facility is used to utilize the tidal difference that occurs between two sea areas that are separated by a land mass, for the production of electrical energy, in that a rotary device is driven by a water current that is created in a connection between the sea areas, for the operation of a power generator.

In some places along the globe's coasts, geographical and topographic conditions mean that sea areas with different tidal patterns and thus different sea levels lie close to each other as the crow flies, but are separated from each other by land masses. Such permanent changes in the vertical movement pattern of the water bodies can be utilized for power production by means of a technically constructed horizontal connection through the land mass between the water bodies

Description of the invention in connection with figures.

The invention shall be explained in more detail with reference to the subsequent figures in which. Figure 1A shows a first embodiment of the present invention, where there is a permanent time shift in the tidal cycle between two sea areas, and which one wishes to exploit according to the invention, and this tidal cycle is illustrated in Figures 3 and 4A-4B. Figure 1B shows a plan view of a fjord system where, by analogy, exploitable tidal differences occur between two localities. Figure 2 shows a second preferred embodiment of the invention where there is a permanently different tidal pattern between two sea areas, as there is a constant different amplitude as shown in figures 5 and 6. Figures 7 and 8 show a situation where the land masses form both a permanent time shift in the tidal cycle and a permanently unequal tidal amplitude. Figure 9 shows a preferred embodiment of a facility in the form of a pipe or a channel for the utilization of energy that can be utilized in an area where two sea areas are separated by a landmass S and where there are different tidal cycles

Figure 10 shows another embodiment of such a facility.

Figure 11 shows a cross-section of a preferred embodiment of a facility for the production of energy.

Figure 12 shows and indicates the dimensioning of the water channel.

Figure 13 shows a longitudinal vertical section of a plant according to the invention for producing energy. Figure 14 A,B,C shows a preferred embodiment of an inlet funnel to the facility's water channel according to the invention.

Initially, reference is made to Figure 1A, which shows two sea areas A and B that are separated by a land mass that forms a natural barrier S. Said land mass can also, for example, include an underwater elongated mountain ridge that projects upwards towards the sea surface, without breaking the surface, and will also normally form a time shift of the tidal difference.

The sea level differences can be characterized by: The barrier's landmasses S and/or topography on the seabed result in a permanent time shift in the tidal cycle between sea areas A and B. The seabed is otherwise denoted by the reference K. If the landmass, as mentioned above, also includes an underwater ridge that juts upwards towards the sea surface, without breaking the surface - there will also then be a time shift in the tidal cycle and, as a rule, also a change in the tidal pattern. At all such locations, a natural tidal current appears. As an additional effect of the present invention, all natural tidal currents can also be utilized for the production of electrical energy. When using the invention at such locations, the artificial tidal current will in reality be a drainage of the natural tidal current. That is to say: the volume of water flowing through the artificial tidal current drains the flow in the natural tidal current by a corresponding volume of water.

According to the invention, a tunnel connection, possibly a channel/pipe connection with a water chute, is arranged through the land mass/barrier S. The elevation heights of the connection/chute must include elevation limits for mathematical high water/low water at

the sea masses on either side of the barrage, plus specified allowances.

Application of the invention at these locations creates new, calculable and controllable artificial tidal currents that can be used for industrial production of renewable electrical power. More than 50 locations around the globe have already been mapped where the invention can be used for the production of electrical power. Collectively, these locations, using the invention, have the potential to produce enormous amounts of electrical energy.

Figure 1A illustrates the invention in general. The designation H on the figure indicates astronomical high tide, while L denotes astronomical low tide. These sizes are almost completely identical for sea areas A and B on either side of the natural barrier S. Sea areas A and B have different levels because topographical conditions create a permanent phase shift in the tidal pattern between A and B. A typical location for this variant is shown in Figure 1B . It shows a fjord area with two fjord systems A and B separated by a land mass 0. Between the two fjord bottoms there is a short stretch with a land mass S which, for example, connects the mainland with a larger peninsula 0. When a tidal wave comes in towards land as shown by the arrows F takes longer to reach the fjord bed B than it does in the fjord bed A. Between the two systems, there is therefore a permanent difference in level that can be exploited. The land mass S can be a low and easily passable hill or a higher mountain ridge that can be pierced by a tunnel to exploit the invention. Figure 4A shows the sine curves for the tidal cycle at the two areas A,B compiled over a period of 24 hours, and labeled "Locality 12/51".

Figure 4B shows an enlarged section of the sine curves for the tidal cycle at the two areas put together. The distance HL indicates (in metres) the astronomical difference between high tide and low tide. The X-axis indicates a time scale for the 24 hours of the day, from 00 to 24. The quantity FG is the phase difference in time between the tidal movements in sea areas A and in B. The distance EK is the phase difference expressed in meters (0.21 m = 21 cm) . The size of EK is in relation to HL and to FG.

In Figures 4A and 4B, the water flow direction is indicated by the shading direction in the fields between the sine curves, i.e. that the shading direction indicates how the artificial water flow varies in size and direction. The shaded fields also express which energy potential lies in the tidal current. It is the size FG that creates the energy potential. Given a FG, the size of HL is important for EK and thereby for the energy potential in the individual project.

In such an artificial tidal flow, the water direction will not change at H or L, but the time of change is determined by the size of FG. It appears that at this location, this shift takes place at around 0600 (morning).

The simultaneous difference in tidal phase for two sea areas and the location-related difference between high tide and low tide will vary with the coordinates for different location pairs. These conditions determine the invention's potential as an energy producer at the individual location. Such natural conditions will affect the concrete design and dimensions of the patent at the individual location. The patent will manifest itself in four main forms.

Reference should now be made to figure 2 which shows another preferred embodiment of the invention. Here there is a permanently different tidal pattern between two sea areas, as there is a constant different amplitude as shown in figures 5 and 6.

In Figure 2, H is shown as an astronomical high tide and L as an astronomical low tide. These sizes are different for the two sea areas C and D on either side of the natural barrier S. Sea areas C and D have different levels because land masses and/or topographical conditions on the seabed create permanently different amplitudes in the tidal pattern of the two sea areas. In Figure 5, the sine curves for the tidal cycle at the two areas are put together corresponding to Figure 4A.

In Figure 6, the shaded fields indicate how the artificial flow will vary in size and direction. The shaded fields also express the energy potential in the artificial tidal flow. At all such locations, the artificial tidal current will not change water direction at high tide H or low tide L. At this specific location (loco 31/51), the artificial tidal current will, as a result of the influence of gravity, always flow in the same direction. The tide's sinus patterns will vary from locality to locality, but sinus patterns at the individual locality are always permanent. At some locations, the artificial tidal current, as in this case, will always flow in the same direction, see Figure 6.

The dimensioning of the water channel V in a tunnel connection T or tunnel/pipe connection between sea areas C and D according to figure 10, will have to include mathematical ebb and flow for both sea areas.

Main shape 1 (Figures 9, 10, 11 and 12).

A first of a total of four main forms of the invention is illustrated in Figure 9. Two sea surfaces, A and B, with a difference in level are separated by a rock ridge S. H shows astronomical spring tides and L corresponds to two low tides.

According to the invention, a plant for power production is designed by blasting out a tunnel 100 shown in Figure 11 transversely through the headland S with an arc-shaped roof vault 101. Initially, the floor surface of the tunnel has a height level 102 which is somewhat higher than the level of the astronomical level H for the spring tide in the area. In this tunnel 100, a channel or chute 104 is further blasted down, and the bottom level 106 in the chute 104 is calculated to have an elevation that is at a slightly lower level than the lowest low water L.

By constructing a water channel as shown in figure 11 in a tunnel T with an upper elevation higher than the astronomical spring tide H and a lower elevation lower than L, you will gain access to an energy-rich tidal flow.

In order to be able to utilize this power potential for the production of electrical power, the dimensioning of the water channel and thus the tunnel must be calculated individually for each location. The width of the tunnel 100 and the roof of the tunnel are determined based on the amount of water to be transported through the water channel 104 in the tunnel. The water channel is laid submerged in the tunnel floor at the same elevation throughout the length of the tunnel. The elevation of the water channel's top point Vt (102), cf. figure 12, is determined by: the high water level H, plus the calculated maximum impact from air pressure, from wind strength and wind direction, plus the calculated magnitude of future sea level rise and the dimensions of the technical means of production to be used to produce the electrical energy. The bottom of the gutter is determined by L plus consideration of the desired volume of water to be transported through the gutter. The water channel, V (104), can be cast in concrete, and optionally lined with metal, plastic or other malleable and durable material, so that the inside of the channel is as smooth as possible, so that it provides the least possible friction against the water flow. The water channel has the character of a channel in the full longitudinal direction of the tunnel floor, as Figure 11 suggests.

At each end of the tunnel, a catchment, safety, discharge zone with a funnel-shaped 200 has been constructed, as can be seen in Figure 14. Figure 14A shows the inlet funnel 200 seen straight from the front, and shows the entrance to the tunnel 100 with the channel/gutter 104 in the tunnel floor. As figure 14C shows, the inlet funnel can have a flat upper side, while the underside slopes upwards towards the chute 104. Figure 14B shows that the funnel tapers from the outer side 202 to the entrance 204 to the channel 104. In the production part, the width of the channel is determined by available/selected water quantities and selected speed of the "tidal flow".

The inlet funnel must serve several considerations:

• It must ensure flexible water in and out.

• It is used to determine the amount of water/flow rate in the water channel. Makes the internal cross-section of the water channel y sq.m., while the same section at the end of the catchment zone is 3x y sq.m., this could increase the water pressure towards the channel 104 and thereby triple the water's speed in

the water channel.

• In this zone, a breakwater, gratings that prevent the ingress of unwanted material and a safety gate (sluice gate) are placed.

As indicated in Figures 11, 12 and 13, unspecified paddle wheels (Sk) are mounted in the water channel one after the other along the entire length of the channel, as Figure 13 suggests 5 such in a row. Skovihjelen's Sk shafts Ax are placed at 90 degrees to the tidal flow. The Skovihjulen's Sk axles Aks are placed so that they are always higher than the water level in the water channel (elevation 102). Shows e.g. site-bound calculations that the most power/cost-effective paddle wheels must have a diameter of 9.5 meters and a width of 14 meters, this means that such a paddle wheel can, for example, be placed every ten meters across the tunnel 100 and that the water channel 104 itself must be just over 14 meters wide. Skovihjelen's Sk axle Aks is mounted directly or via exchange to two unspecified generators (Gi or G2), one at each end of the axle. Figuratively speaking, each paddle wheel drives two windmill generators. Alternatively, each paddle wheel can drive a larger generator. Economic assessments determine this. The length of the tunnel/water channel and the number of paddle wheels/generators are calculated based on the site's topography, the size of the exploitable resource and market economic assessments.

A particular embodiment of the invention can be seen in Figure 13, which is a vertical section through a plant according to the invention. On the floor 102 of the tunnel 101 through the land mass S, an elongated artificial channel 200, for example cast in concrete, is formed. Channel 200 is open upwards. A number of turbines with bladed blades Sk are each stored on their own shaft Aks which extends over the channel across its longitudinal direction. The shaft Aks is connected to two generators Gi,G2, one on each side of the channel 200. It appears that a preferred turbine form is a vane turbine with a number of blades mounted to the shaft which is set across the direction of flow in the channel 200.

Figure 13 also shows a longitudinal view seen directly from above or seen directly from the side, which shows that in this channel 200 there are arranged 5 turbine/generator systems which are driven by the body of water.

The shortest connection between A and B will not necessarily be the most cost-effective, as such a facility must preferably be designed with several buckets in a row in the channel. The channel can therefore be designed in an arc shape between the two areas, and consequently the channel can be placed through the land mass at a distance from the shortest connection between A and B. The balance between tunnel length, width, height and depth must be calculated based on the natural characteristics -istics for each individual project.

A second main form is shown in Figure 15.

This design is constructed as a pipe street (channel) 300 through the land mass S below the lowest sea level L (foreshore). Rørgaten 300 is leveled at the same elevation, e.g. -15 meters below sea level, in the full length of the water course. The pressure differences between sea levels A and B will drive the "tidal flow" through the pipe street 300. Such a solution can be used at all locations, also as an alternative to Main form 1. With such a design of the idea, one would have to use cross-aligned, unspecified, directly connected turbines or via exchange/transfer to unspecified generators, to transfer the water flow into electrical energy. If the generators are placed in the pipe as extensions of the turbines themselves, figuratively like "clipped wind turbines", the generators will eat up meters of space in the water flow. If the generators are placed in pockets on the outside of the pipe street, and operated via exchange/transmission, the turbines will be able to stand closer to each other along the entire length of the pipe street. At the ends of the pipe street, there must be a catchment, safety and discharge zone with the same functions as shown in figure 14.

A third main embodiment of the invention.

The natural form of the locality has a character that makes it impossible to incorporate the invention into the mountains. If you want the patent carried out at sea level, this must be carried out as a water channel in the form of a channel, through loose masses (possibly low solid rock) on land, through loose masses in the tidal bed and out to the marshland, on both sides of land. The tidal current can be utilized in the full length of the watercourse, according to the same principle as with Main form 1. Main form 2 can be used as an alternative in such locations.

A fourth main embodiment of the invention.

Different combinations of execution no. 1 and 3 mentioned above. In this description, the term sea area includes everything from the meeting of the great ocean with the coast, sea bays, fjords, fjord arms, inlets and all other topographical forms where the sea water reaches at high tide.

Claims (16)

1. Method for producing energy from a stream of water, in which a rotary device rotates or rotates and drives a generator for producing said energy, characterized in that it is produced through a channel connection arranged through a land mass which defines a separation between two sea areas with different tidal cycles, a water flow as a result of the different sea levels between the two sea areas, where the separation leads to a phase shift in the sea areas' tidal cycles, and said rotation device is arranged in the water flow for to produce said energy, as an upwardly open channel is used whose upper level (102) is located above the astronomical tide level of the two sea areas (A-B; C-D), the channel's bottom level (106) is lower than the mathematical tide level of the two sea areas. 2. Method in accordance with claim 1, characterized in that a connection is used in the form of a channel whose bottom is arranged at the same elevation throughout the length of the channel. 3. Method in accordance with claim 1, characterized in that a connection in the form of a channel (300) is used through the land mass (S) at a distance below the two sea levels, the channel (300) being defined at the same elevation throughout the length of the channel . 4. Method in accordance with claim 1, characterized in that a water channel (104) is used which is internally covered with a material that provides the least possible friction against the water flow, which material is preferably metal sheets, plastic or other malleable and durable material. 5. Method in accordance with claim 1, characterized in that an inlet funnel is used to accumulate the water volume into the channel, and that means are used to determine the amount of water and flow rate in the channel. 6. Plant for the production of energy from a stream of water, comprising a rotary device which can be driven by the stream of water for operating a generator for the production of said energy, characterized by a channel arranged through a land mass which defines a separation between two sea areas with different tidal cycles, in order to establish a water flow as a result of the different sea levels between the two sea areas, and which separation leads to a phase shift in the sea areas' tidal cycles, and said rotary device is arranged to to be arranged in the water flow to produce said energy, as the channel's upper level (102) is located above the astronomical tide level of the two sea areas (A-B; C-D), and the channel's bottom level (106) is lower than the mathematical tide level of the two sea areas.. 7. Installation in accordance with claim 6, characterized in that the bottom of the channel connection is arranged at the same elevation throughout the length of the channel. 8. Installation in accordance with requirements 6-7, characterized in that the channel is open at the top. 9. Installation in accordance with claims 6-8, characterized in that the channel (300) runs through the land mass (S) at a distance below the two sea levels, the channel (300) being defined at the same elevation throughout the length of the channel. 10. Installation in accordance with claims 6-9, characterized in that the channel is internally covered with a material that provides the least possible friction against the water flow, which material is preferably metal sheets, plastic or other malleable and resistant material. 11. Installation in accordance with claims 6-10, characterized in that each end of the channel comprises a funnel-shaped zone to increase the in/out of water in the channel, and to determine the amount of water/flow rate in the water channel. 12. Installation in accordance with claims 6-11, characterized in that each inlet end includes breakwaters and a blocking device for unwanted material, as well as possibly a sluice gate that can stop the water flow at any time. 13. Installation in accordance with claims 6-12, characterized in that a number of water turbines are used which drive generators which produce electrical energy. 14. Installation in accordance with claims 6-13, characterized in that the channel is arranged buried in the floor of a tunnel that is unshaped through the land mass. 15. Installation in accordance with claims 6-14, characterized in that the channel is arranged as an artificial chute standing on the floor of a tunnel that is unshaped through the land mass. 16. Application of the tidal difference that occurs between two sea areas that are separated by a land mass, for the production of electrical energy, by a rotary device being driven by a water current that is created in a connection between the sea areas, for the operation of a power generator.