BE1018122A3 - Power generation device, has fluid compartment filled with fluid, where fluid in compartment is pumped to individually separated spaces, and potential energy generated by fluid movement is transferred to generators - Google Patents

Abstract

The device (1) has a fluid compartment (2) filled with a fluid in which a load (6) floats. A collecting tank (12) is provided at a lower part of the fluid compartment, and a barrel (14) is provided at a top part of the fluid compartment, where the fluid in the compartment is pumped to individually separated spaces (8) by control of individual valves (10a, 10b), and potential energy generated by fluid movement is transferred to generators (7a, 7b). The compartment is connected to the individually separated spaces through gently sloping channels (9a, 9b). An independent claim is also included for a method for generating energy.

Description

Device and method for generating energy

The present invention relates to a device for generating environmentally friendly energy, by making use of the potential energy of a load that floats on a liquid surface, and whereby a cycle of liquid displacement within different compartments is effected.

In addition, the invention relates to a method for generating energy in which a sequential fluid displacement from a first compartment to a plurality of compartments is controlled and thereby causes a gravitational displacement of a load, whereby coupled generators are put into operation.

Intensive exploitation of fossil fuels, on the one hand and, on the other hand, our present and future society being confronted with serious environmental problems, of which global warming, global warming and climate change are just a few indicators, partly due to the use of fossil fuels. fuels, people look for alternative forms of energy.

The rise of wind energy, tidal energy, wave energy, hydrodynamics, solar energy, etc. are just a few examples. These forms of so-called "green energy" should allow us to offer an alternative to traditional forms of energy.

In addition, these energies are only in their infancy and the return as a function of cost is still insufficient to use them economically as a worthy replacement.

In addition, some of the aforementioned energy technologies cause problems with regard to the environmental image and are disorienting in the biotope. We are thinking, for example, of the wind turbines.

In the prior art, however, numerous devices are known in which energy is generated by using bodies that are immersed in a liquid according to the so-called Archimedes principle.

Such devices have the drawback that they are rather complex in structure and thereby increase the risk of a failure or breakage of a component.

Another important problem is that the energy demand is usually not constant over a certain period of time. At peak moments, as a result of a higher energy demand, a sufficient quantity must be able to be supplied, while at a lower energy demand, the generated energy must be able to be stored.

Our invention has the first advantage that it can develop sustainable energy on the basis of a relatively simple device without involving huge maintenance costs and whereby the energy supply is kept to a minimum.

The device can be used and manufactured both on an industrial scale and for domestic use. This invention can be installed in various places, such as below the earth's surface, such that the surrounding image is not disturbed, which provides a second advantage.

This invention furthermore has the third advantage that the device is provided with a mechanism for the temporary storage of the energy generated by means of compressed air, with the aim of being able to meet the energy demand during peak moments.

The invention thus essentially consists of a first compartment in which a load floats on a liquid. This first compartment is in communication with individual spaces which are separated from the first compartment by shut-off valves. By controlling the valves, the fluid can selectively flow from the first compartment to the individual separate spaces. These individually separated spaces serve as temporary reservoirs. This causes the load to be moved downwards. The load is linked to a number of generators.

The device subsequently consists of a third compartment, the top surface of which is located at the level of the base of the two aforementioned compartments. This compartment is respectively connected to the first compartment and to a higher-lying vessel, the bottom surface of which is located at the level of the upper surface of the first two compartments.

This vessel is connected to a compressor and is connected to the first compartment.

A cycle is effected by this device in which a liquid flows from a first compartment, step by step, to individual spaces and the load moves gravitally to the base of the first compartment.

A first cycle is started by lowering the load located at the top of the liquid column by opening a first valve, the liquid flowing from the first compartment to a first space. In this way the load sinks into the liquid column of the first compartment and the various spaces are successively filled with liquid, by controlling the valves.

However, an amount of liquid now located at the bottom of the first compartment must be transferred to a reservoir that is lower than the first compartment and the adjacent spaces. The liquid that enters the reservoir must be pumped back into the first compartment to start a second cycle.

The method consists of a number of steps in which a liquid is moved from a first compartment in which a load floats to temporary collection reservoirs, which are separated from the first compartment by valves and which are sequentially opened and closed by a control. This allows the potential energy of the load to be used to generate electrical energy.

The invention is explained in more detail on the basis of the accompanying figures.

FIG. 1: cross section of the device

FIG. 2: section of compartment with load

FIG. 3: sectional compartment with displaced load

FIG. 4: cross-section of temporary reservoirs

According to figure 1, the device (1) consists of a compartment (2), which is provided with side walls (3a, 3b) and a bottom plate (4). The compartment (2) has a shape such that the height is preferably greater than the width and can be beam or cylindrical. Depending on the use that can be used both on an industrial scale and by individual households, will. the capacity of the device (1) can be adjusted. This also means that the contents of the compartment (2) can be adjusted in function of the aforementioned.

According to a possible and calculated embodiment, the compartment (2) has a height of approximately 60 m. The compartment (2) is filled with a liquid (5), which is preferably water. Under certain circumstances, a solvent can be added to make the device function under various conditions. At very low or very high temperatures, the properties of the liquid can be adjusted as a result.

At the start of a cycle, a floating load (6) is located at the top of the compartment (2). The load (6) is provided in such a way that the space between the load (6) and the walls (3a, 3b) of the compartment (2) is 2 to 3 cm. The load (6) is also connected to generators (7a, 7b), which convert the potential energy (Epot) into electrical energy. The number of generators (7) depends on the capacity of the device (1).

According to a possible embodiment, the energy generated by the generators (7a, 7b) can be converted into compressed air by providing at least one compressor and wherein the generated compressed air can be stored in at least one pressure vessel. If the energy demand increases, the compressed air is released by means of an air motor, such as a turbine, for driving at least one electric generator. Through this device, the energy generated can be connected directly to a network or device via the principle of the load or via stored compressed air, depending on the energy demand. However, this is not indicated in the figures.

Storing the energy in a pressure vessel, whereby at least one compressor is activated, is controlled by a control. With a low energy demand the generated energy is stored, while with an increased energy demand the compressed air from the pressure vessel activates an air motor, which activates an electric generator to generate additional energy. The control ensures an adjusted energy management according to the energy requirement.

According to calculations and in accordance with this possible embodiment, the load consists of a ship that has a weight of 73400 tons. To generate a power of 2,106 watts for 6 hours, a load of approximately 73400 tons is required according to the potential energy (Epot), expressed in Joule (J), according to Epot = mgh, where m is the mass (kg), g fall acceleration (9.81 m / s2) and h the height (m) of the load (6).

The compartment (2) is connected on one side wall (3b) to a number of individually separated spaces (8), each with a height of 1 m. These separated spaces (8) are not mutually connected. The compartment (2) and the individually separated space (8) are in communication with each other by means of two slightly inclined connecting channels (9a, 9b), each of which is provided with a closable valve (10a, 10b), which can be electromagnetically controlled. A first connecting channel (9a) is slightly sloping in the direction of the individually separated space (8), while the other connecting channel (9b) is sloping in the direction of the compartment (2). The vertical structure of the number of individually separated spaces (8) is proportional to the content and the height of the compartment (2).

In figure 1, however, not all individually separated spaces (8) are shown proportionally. According to this embodiment, in which the compartment (2) has a height of 60 m, 56 individually separated spaces (8) are thus provided and the lower 2 m and the upper 2 m are not used as a receiving space for this.

According to a possible embodiment, the compartment (2) is centrally located with respect to the separate spaces (8). According to figure 1, only one column of separate spaces (8) is provided. According to this possible embodiment, at least 2 columns of separate spaces (8) are provided, which are located around the periphery of the centrally located compartment (2). Preferably, 4 columns of separate spaces (8) are provided. However, this is not indicated on the figures.

The device (1) is provided at the bottom with a base plate (4), above which a channel (11) is formed, which connects compartment (2) to the underside of the column of individually separated space (8).

The channel (11), which slopes slightly from the bottom of compartment (2) in the direction of the individually separated spaces (8), flows into a receiving tank (12). The content of the collecting tank (2) is provided in such a way that the remaining amount of liquid from compartment (2) can be collected therein. This is therefore the case when all individually separated spaces (8) are full.

A closable valve (13) is provided in the channel (11). The upper surface of the collecting tank (12) is located deeper than the lower side of the column of individually separated spaces (8).

A vessel (14), the bottom surface of which is higher than the top of the column with the individually separated spaces (8), is connected to compartment (2) by means of a channel (15). A lockable valve (16) is also provided in the channel (15).

The vessel (14) is provided with a compressor (17) for the purpose of sending air from the vessel (14) through a guide (18) provided with a valve (19) to the receiving tank (12).

The liquid is transferred from the collecting tank (12) to the vessel (14) by means of a guide (20). A valve (21) controls the flow.

The control of the valves (10, 13, 16, 19, 21) is done by a unit that operates a pre-programmed control. The liquid level (5) can be detected on the basis of optical sensors in order to operate the valves.

A portion of the energy generated by these cycles can be used to drive the compressor and any other sources.

The device (1) is preferably manufactured in resistant and durable materials such as reinforced concrete and stainless steel.

If the device (1) is used for domestic use, it can be installed in an underground cellar.

The device can optionally be provided with additional energy sources such as photovoltaic cells or a wind turbine.

The operation and method of the device (1) are then explained.

According to Figure 2, the load (6) is in the highest position, namely at the top of the compartment (2). The generators are not indicated in this figure. At the start of the cycle, the liquid level (5) in the compartment (2) is always higher than the next adjacent individually separated space (8). The cycle is started by opening valve (10a), through which the liquid flows from compartment (2) via a connecting channel (9a) into a first individually separated space (8). However, the valve (10b) remains closed. This is illustrated with the help of figure 4. The upper individually separated space (8) is filled with the liquid and the load (6) drops into the compartment (2) at a distance that is proportional to the amount of liquid that drained away.

The load (6) is now in a position as indicated in figure 3. The process is repeated by always flowing the liquid from compartment (2) to the respective individually separated spaces (8), as indicated above by the valves ( 10a) or from top to bottom.

Once the load (6) has reached the lower separated space (8), a residual amount of liquid remains in the compartment (2). This liquid is located in channel (11), which is closed by valve (13). Upon opening the valve (13), the liquid flows into the collection tank (12). By means of the compressor (17) the air is sent via a guide (18) by opening a valve (19) to the receiving tank (12). As a result, the liquid is transferred from the collecting tank (12) to the vessel (14) via a guide (20). The valve (21) is then closed.

The liquid is returned to the first compartment (2) via the channel (15) by opening the valve (16) of the vessel (14). The load (6) is brought back to its highest point in compartment (2) by respectively opening the valves (10b) from bottom to top in the connecting channels (9b), the liquid moving from bottom to top in the compartment (2) fills.

This allows the cycle to repeat itself.

The method for generating environmentally friendly energy consists of a few consecutive steps.

A liquid in a first compartment is moved by a valve control to adjacent compartments, as a result of which a load that floats on the liquid in the first compartment moves by gravity.

The displacement of the load is such that the lowest adjacent compartment is reached, and the remaining liquid flows from the first compartment to a lower compartment.

The liquid is then transferred to a vessel located higher than the first compartment, from which it flows back to the latter.

Finally, the valves of the adjacent compartments are opened to return the load to its highest position.

Claims (17)

A device (1) for generating energy consisting of a first compartment (2) filled with a liquid in which a load (6) provided with generators (7a, 7b) floats, a number of adjacent individually separated spaces (8) ), a collecting tank (12) that is lower than the bottom surface (4) of the first compartment (2) and a vessel (14) that is higher than the first compartment (2) and characterized in that the liquid from the compartment ( 2) can be moved to the adjacent individually separated spaces (8) and vice versa by the control of individual valves (10a, 10b) with the result that the potential energy of load (6) is transferred to the generators (7a by the fluid displacement) 7b). A device (1) for generating energy according to claim 1 and characterized in that the number of adjacent individually separated spaces (8) are provided such that they are in proportion to the capacity of the first compartment (2). A device (1) for generating energy according to claims 1-2 and characterized in that the first compartment (2) is connected to the individually separated spaces (8) via a first slightly sloping channel (9a) in the direction of the latter and a second slightly sloping channel (9b) in the direction of the first compartment (2) which are respectively controlled by the valves (10a, 10b). A device (1) for generating energy according to the preceding claims and characterized in that the compartment (2) is centrally located and is surrounded around its periphery by at least 2 columns of separated spaces (8). A device (1) for generating energy according to claim 4 and characterized in that the centrally located compartment (2) is surrounded by 4 columns of separated spaces (8). A device (1) for generating energy according to claims 1-5 and characterized in that the compartment (2) is connected to a collecting tank (12) via a slightly sloping channel (11) with a valve (13). A device (1) for generating energy according to claims 1-6 and characterized in that the vessel (14) is provided with a compressor (17), an air line (18) with a valve (19) and a guide (20) with valve (21) communicating with the receiving tank (12) and wherein the vessel (14) communicates with compartment (2) via a light-sloping channel (15) with a valve (16). A device (1) for generating energy according to claims 1-7 and characterized in that the device (1) is made from a reinforced concrete or stainless steel. A device (1) for generating energy according to claims 1-8 and characterized in that the device (1) is arranged underground. A device (1) for generating energy according to the preceding claims and characterized in that the valves (10, 13, 16, 19, 21) are controlled by a pre-programmed control. A device (1) for generating energy according to claim 10 and characterized in that the valves are electromagnetically controlled. A device (1) for generating energy according to the preceding claims and characterized in that the generated energy can be supplied directly or as stored energy in the form of compressed air to a network or a device via the generators (7a, 7b). A device (1) for generating energy according to claim 12 and characterized in that the energy from the generators (7a, 7b) is converted into compressed air via at least one compressor in a low energy demand and stored in at least one pressure vessel in order to an increased energy demand to operate an air motor that drives at least one electric generator. A device (1) for generating energy according to claim 13 and characterized in that the energy storage in at least one pressure vessel and the operation of the air motor are controlled via a control according to the energy requirement. A method for generating energy consisting of the movement of a liquid from a first compartment to a number of adjacent individually separated spaces, respectively from top to bottom, whereby a floating load in the first compartment drops due to gravity in the latter compartment until the lowest individually separated space reaches the displacement of the remaining liquid in the first compartment to a lower compartment the displacement of the liquid from the lower compartment to a compartment higher than the first compartment the displacement of the liquid from the adjacent individually separated spaces to the first compartment, respectively from bottom to top, which increases the load in the first compartment, the movement of the liquid from the higher compartment to the first compartment A method for generating energy according to claim 15 and characterized in that the displacement of the liquid is controlled by automatically controlled valves. A method for generating energy according to claims 15-16 and characterized in that the generated energy is supplied directly or in the form of stored compressed air to a network or a device.