RU2118706C1 - Environmentally friendly power plant - Google Patents

Abstract

FIELD: power-plant engineering; mechanical energy generation by using temperature difference and density of sea water at its different levels. SUBSTANCE: power plant has pipeline 1 with open top part placed above water surface and bottom part immersed into deep layers of sea water with low temperature T₁. Pipeline communicates at warm surface layer having temperature T₂ through hole 2 with tank 3 isolated in surface layer of water and made free to communicate with atmosphere. Cold water stream emerging from deep layers due to discharge of denser cold water with temperature T₁ to not so dense warm water with temperature T₂ in surface layer is formed in flow system of pipeline 1, hydraulic motor 6, tank 3, and pipe connection 5. Water lift takes place like in communicating vessels due to hydrostatic forces without requiring additional energy. EFFECT: provision for generating mechanical energy without consuming fuel resources. 4 cl, 2 dwg

Description

 The invention relates to a device for producing environmentally friendly mechanical rotational energy without spending any fuel and energy resources and without creating structures that have a harmful environmental impact on the environment. The invention can be applied as a stationary source of mechanical energy of rotation with the possibility of converting it into electrical energy.

 Known hydraulic units consisting of a hydraulic turbine and an electric generator (see Polytechnical Dictionary. - M.: Soviet Encyclopedia, 1980, p. 115).

 Hydraulic units are commonly used in hydroelectric power plants, including expensive water dams, creating reservoirs that lead to flooding of the land and environmental changes in the surrounding area.

 Closest to the proposed invention in terms of features is a device for producing environmentally friendly mechanical rotational energy, containing a rotor partially immersed in water, around the circumference of which are heat-sensitive elements connected with the load in the form of a massive rim with the possibility of its radial movement with changing ambient temperature, the upper and lower parts of the rotor are located respectively in the heating and cooling zones, the first of which is ambient air, and the second is formed by an open top surface placed in a warm water layer capacitance as a tray with walls above the surrounding water level, which communicates with the upper part of the pipe rising upward, both the communicating vessels, the cold water from the interior of its layers. The rotor is equipped with blades for moving water along the tray from the top of the pipeline towards the surface layer of water. The rotation of the rotor is due to the moment of gravity created by the load at different distances of the side parts of the rim from the axis depending on the heating and cooling of the heat-sensitive elements (see RF patent N 2057645, CL F 03 G 7/05, 7 / 06.1997) .

 The disadvantage of this device is the use of heat-sensitive elements having a relatively complex device and made of expensive materials.

 The invention ensures the achievement of a technical result, which consists in obtaining environmentally friendly mechanical energy of rotation with the possibility of converting it into electrical energy while simplifying the device and reducing its cost.

 The specified technical result is achieved by the use of an environmentally friendly power plant containing heating and cooling zones, the latter of which is made in the form of a container isolated in the surface layer of water and connected to the air, filled with cold running water, supplied through a pipe connected to the tank, lowered into the lower cold layers of water and a communicating vessel relative to the surrounding water, the upper part of which is located above the surface layer of water and freely communicates with ambient air, while in the lower part of the tank there is a bottom hole through which free outflow of denser cold water from the tank into the surrounding surface layer of more or less dense water is carried out, which is a heating zone, and a continuous flow of cold water through the pipeline is ensured as along a communicating vessel and vessel from its deep layers to the surface layer, and a hydraulic motor is installed in this stream.

 The pipeline is composed of two parts - lower and upper, and a hydraulic motor is placed between these parts of the pipeline.

 The hydraulic motor is connected to the hydrogenerator with the possibility of converting the energy of the water flow into electrical energy.

 The bottom hole in the tank is aligned with the pipe facing down.

 The attached diagram shows a general view of an environmentally friendly power plant. The hydraulic motor is conventionally shown in the form of a rectangle, since it may be different from the following device. The tank and top of the pipeline are shown with partial cutouts in the front walls.

Information confirming the possibility of carrying out the invention is given by the example of sea (ocean) water. It is known that the average annual temperature of the surface waters of the ocean and its seas is 17.5 ^o C, and at the equator up to 28 ^o C. Moreover, seasonal temperature fluctuations are observed to a depth of 100-150 m, and in the lower layers it is constant and is about 1 , 5 ^o C. Consequently, the average temperature drop of the oceans between the surface and deep layers is 16 ^o C and maximum up to 26.5 ^o C (see the above "Polytechnical Dictionary", S. 920-921). This temperature difference determines the greater density of water at a low temperature and its lower density at a higher temperature. Communicating vessels are also known in which the property of a liquid is used to move in these vessels in vertical directions, including upward, and to be installed in these vessels in equilibrium with respect to hydrostatic forces acting on the liquid without additional energy costs (see "Soviet Encyclopedic Dictionary". - M .: Soviet Encyclopedia, 1987, p.1245).

 The difference in the density of water at different temperatures in combination with the use of the above properties of communicating vessels allows you to create a continuous flow of liquid in the vertical direction from the bottom up. An inexhaustible source of thermal energy of sea water due to the constant temperature difference of its surface and deep layers provides the implementation of this method of water movement in almost perpetual motion mode, that is, continuously, without the expense of any fuel and energy resources and material resources and without pollution the environment.

An environmentally friendly power plant (see diagram) contains a pipeline 1, lowered into the deep layers of sea water with a low temperature T ₁ , the upper part of which is open and placed above the water level. At the level of the surface warm layer of water with a temperature of T _{2, a} hole 2 is made in the side wall of the flowing part of the pipeline, communicating with a container 3, which is placed in the surface water layer. The upper part of the tank has free communication with the atmosphere and is located above the water level. The internal volume of the tank is isolated from the surrounding water and communicates with its surface layer only through a freely flowing bottom hole 4 in the lower part of the tank. The hole can be combined with a downwardly directed short pipe 5 located in a surface warm layer of water. A connector is made below the tank in the pipeline, and a hydraulic motor 6 is placed in it, which can be made in the form of well-known hydraulic turbines or volumetric hydrostatic engines (see the Polytechnical Dictionary mentioned above, p.114). The hydraulic motor is connected to an electric power generator (not shown in the diagram).

 The power plant operates as follows.

 To start the installation from a stationary position with the help of an auxiliary pump, forced movement of cold water from the deep layer through pipeline 1, hydraulic motor 6, tank 3 and bottom hole 4 to the surface of the water layer is performed. This pump is turned off after filling the entire specified system with cold water from its deepest layer.

The feasibility of creating a water flow in the above order is ultimately due to the fact that they provide heat energy exchange between warm water from the surface layer and water from the deep layer having a low temperature T ₁ , which determines their different density and the possibility of movement of denser cold water through the bottom the hole 4 in the lower part of the tank 3 within the less dense warm water in the surface layer.

 When this occurs, a flow of denser cold water from the hole 2 in the side wall of the pipeline 1 through the tank 3 and the bottom hole 4 to the surface layer of less dense warm water. The continuity of this flow is ensured by the fact that the hole 2 in the side wall of the pipeline is larger in area than the bottom hole 4 in the lower part of the tank. Draining water from the upper part of the pipeline into the tank leads to the movement of water in the pipeline from the bottom up under the action of hydrostatic forces from the side of the water surrounding the pipeline. In this case, the rise of water in the pipeline occurs as in a communicating vessel relative to the surrounding water.

 Combined with the bottom hole 4, the downward facing pipe 5 facilitates the discharge of dense cold water from the tank into the limits of warmer and less dense water from its surface layer.

The possibility of creating a water flow in the above manner is confirmed by the calculated data. It is known that the density of water is inversely dependent on its temperature (anomalous deviation at 4 ^o C is not considered here). Based on this, the level of the denser cold water (for example, at 2 ^o С) in the pipeline and tank will be lower than that of the surrounding water, the average density of which in the range of the depth of the pipeline will be determined by the average temperature of its deep layer (for example, the same 2 ^o C) and the surface layer (for example, 26 ^o C), which will average 12 ^o C. These temperature indicators (12 and 2 ^o C) will determine the difference in the levels of the surface water layer and the water level in the tank and pipeline.

However, different values of the density of water in the tank and in the surface layer will be determined by the temperature in the surface layer (26 ^o C) and in the tank (2 ^o C).

Based on the fact that the water levels in communicating vessels (in this case, in the pipeline and tank relative to the surrounding water) depend on its density in these vessels, and the density is inversely dependent on temperature, it follows that the high density of water in the tank compared with the surface layer at a temperature difference of 24 ^o C will ensure the outflow of water from the tank, since differences in water temperatures, determining their different densities in the tank (2 ^o C) and the surface layer (26 ^o C), are significantly larger compared to the differences in average th largest ambient water temperature (12 ^o C) and the water temperature in the container (2 ^o C) defining different levels of the surrounding water and water in the container.

 Or, to put it another way, the temperature conditions of the system are such that the influence of different density of water on the creation of its flow from the tank is more significant compared to the difference in its levels in the surrounding body of water and in the tank.

 The water flow passing through the hydraulic motor 6 drives it, which ensures, through the use of a hydrogenerator, the conversion ultimately of the energy of the water flow into electrical energy.

 Due to the small difference in the density of cold and warm water, the described power plant will have a corresponding insignificant specific power as compared to other autonomous power plants. However, even with a low specific power, this power plant will be more efficient compared to the existing energy systems of the fuel and energy complex (FEC) with its mines, quarries, boreholes, pipelines, railways, tankers, other vehicles, power plants, including the most dangerous in all respects nuclear power plants, places of storage and burial of waste, dams and locks of hydroelectric power stations in combination with all this irreparable and ever-increasing environmental damage, alienated land and huge labor costs. In industrialized countries, up to 30% of all capital investments are spent on the development of the fuel and energy complex and up to 20% of all employees are employed in it (see the Polytechnical Dictionary mentioned above, p. 532). At the same time, the fuel and energy complex is actually functioning with inevitable disasters, often affecting entire regions.

 In contrast to this, the proposed environmentally friendly power plant, using the inexhaustible energy resources of the World Ocean and the constant temperature difference between its surface and deep layers, works autonomously with a small number of maintenance (observing) personnel in almost perpetual motion mode, since, without consuming any fuel and energy resources and without polluting the environment, is able to continuously produce electrical energy. During the operation of the power plant, any damage to it cannot cause serious environmental consequences.

Claims (4)

 1. An environmentally friendly power plant containing heating and cooling zones, the last of which is made in the form of a container isolated in the surface layer of water and connected to the air, filled with cold running water, supplied through a pipe connected to the tank, lowered into the lower cold layers of water and which is a communicating vessel with respect to the surrounding water, the upper part of which is located above the surface layer of water and freely communicates with the surrounding air, characterized in that in the lower part This tank has a bottom hole through which free outflow of denser cold water from the tank into the surrounding surface layer of warmer and less dense water is carried out, which is a heating zone, and a continuous flow of cold water through the pipeline, as through a communicating vessel, is provided from its deep layers to the surface layer and in this stream a hydraulic motor is installed.  2. Installation according to claim 1, characterized in that the pipeline is composed of two parts - lower and upper, and a hydraulic motor is placed between these parts of the pipeline.  3. Installation according to claim 1, characterized in that the hydraulic motor is connected to a hydrogenerator with the possibility of converting the energy of the water flow into electrical energy.  4. Installation according to claim 1, characterized in that the bottom hole in the tank is aligned with the pipe facing down.