SE530010C2 - Hydroelectric power plant and method for extracting electricity by means of a hydroelectric power plant - Google Patents

Description

550 010 Said turbine is exposed to the vertically flowing water by being arranged at a position where the falling water is led. This kinetic energy of the water masses is converted into kinetic energy of the turbine, which is connected in a conventional manner to a generator which converts the kinetic energy into electricity, which after appropriate treatment can be distributed in appropriate form and strength.

Thus, a conflict of interest arises between the theoretical possibility of erecting another Hydropower Plant upstream or downstream of the existing hydropower plant, and the environmental considerations that form the basis for the ban on additional Hydropower Plants.

OBJECTS AND FEATURES OF THE INVENTION The present invention aims at eliminating the above-mentioned conflict of interest in previously known hydropower plants and creating an improved hydropower plant.

A primary object of the invention is therefore to create a hydroelectric power plant which can extract a larger amount of electricity than a conventional hydroelectric power plant built on the same site. Another object of the invention is to provide a hydroelectric power plant which is the result of a relatively low development cost per kilowatt obtainable and the plating of a conventional hydroelectric power plant, without negative environmental consequences.

The object of the present invention is achieved by means of the initially defined hydropower plant and the initially defined method, which are characterized by the features found in the independent claims. Preferred embodiments of the present invention are further set forth in the dependent claims.

According to a first aspect of the present invention there is provided a hydroelectric power plant of the introductory type defined, which is characterized in that the same 530 010 also comprises a second turbine connected to a second generator, which is located at a position upstream of said first turbine in the vicinity of the inlet of the hydropower plant, and which is arranged to be exposed to horizontally flowing water.

According to a second aspect of the present invention, there is provided a method of initially defined kind, comprising the steps of placing a first turbine connected to a first generator at a position in a water flow channel present in the hydropower plant and subjecting said first turbine to vertically flowing water, and placing a second turbine connected to a second generator in the vicinity of the inlet of the hydropower plant and exposing said second turbine to horizontally flowing water.

Thus, the present invention is based on the insight that more energy than conventional hydropower plants can extract from an existing watercourse can be recovered by means of the hydroelectric power plant according to the invention.

In a preferred embodiment of the present invention, the water flow channel of the hydropower plant consists of a siphon line extending from the inlet of the hydropower plant to its outlet, and that said first turbine is arranged in this siphon line.

Brief Description of the accompanying Drawings A more complete understanding of the above and other features and advantages of the present invention will become apparent from the following detailed description of preferred embodiments taken in conjunction with the accompanying drawings, in which: Fig. 1 is a schematic representation of a river stretch, and Fig. 2 is a schematic representation of the hydropower plant according to the invention. 530 010 Detailed Description of Preferred Embodiments Fig. 1 shows a schematic representation of a river stretch where a first rapids stretch, designated A, and a second rapids stretch, designated B, are found. How the river otherwise looks upstream and downstream of the part shown is largely unimportant. Downstream of the first rapids section A and upstream of the second rapids section B there is a calmer section, for example in the form of a lake with more or less constant volume, ie. the inflow to the lake is essentially as large as the outflow from the lake. Furthermore, the calmer part does not necessarily have to be preceded by a rapids section A or be in the form of a conventional lake. Assume further that the above-mentioned, underlying problem exists as a prerequisite, more specifically that the first rapids section A cannot or may not be "expanded". In other words, it is prohibited by law or otherwise improperly to exploit this first rapids by erecting a hydroelectric power plant. However, it is quite possible to build a hydroelectric power plant according to the invention at the second rapids section B, where the intermediate lake passes to the said second rapids section B. It may also be the case that a conventional hydroelectric power plant has previously been built at a crossing point C.

Referring now to Fig. 2, there is shown an inventive according to Hydropower Plant 1. Hydropower Plant 1 comprises in a conventional manner a first turbine 2, which is located at a position in a water flow channel 3 present in Hydropower Plant 1, which extends from hydropower plant 1. the inlet of the power plant 1 to its outlet and through which the water masses flow. Thus, said first turbine 2 is arranged to be exposed to vertically flowing water when the hydropower plant 1 is in operation. By the wording "arranged to be exposed to vertically flowing water", as used in the description as well as in the following claims, is meant that the first turbine 2 is located to extract the difference in potential energy that the water masses possess 530 010 upstream of the hydropower plant 1 in relation to downstream of the hydropower plant 1, the hydropower plant 1. arranged to extract the change in potential energy, i.e. which is converted into kinetic energy in In other words, the first turbine 2 is essentially vertical kinetic energy.The location of said first turbine 2, as shown in Fig. 2, should only be seen as an example and thus it may be located at a different and possibly more advantageous position depending on the construction and type of the hydropower plant 1. It should be pointed out that even if the first turbine 2, according to an exemplary embodiment not shown, is arranged at a position where the water flow channel 3 again has a horizontal extension, ie for example in the vicinity of the outlet of the hydropower plant 1 according to figure 2, said first turbine 2 is considered to be exposed to vertically flowing water. The above formulation is thus that the first turbine 2 The central is exposed to Masses of water whose potential energy has been converted into kinetic energy in the hydropower plant 1.

In the exemplary embodiment shown in Fig. 2, the hydropower plant 1 is of the siphon type. This means that the water masses pass a point in the hydropower plant 1 which is at a level which is higher than the water level upstream of the hydropower plant 1 when it is in operation, and thus is sucked through the hydropower plant 1.

The first turbine 2 is connected to a first generator 4 via power transmission means 5. In the embodiment shown, the power transmission means 5 consists of a turbine shaft 5 emanating from the first turbine 2 which transmits the rotational movement of the first turbine 2 to said first generator 4. first generator 4 is furthermore connected in a conventional manner to suitable transformers and converters in order for the extracted electricity to obtain a suitable shape and strength for distribution.

What characterizes the hydropower plant 1 according to the invention is that it also comprises a second turbine 6, which is located at a position upstream of said first 530,010 turbine 2 in the vicinity of the inlet of the hydropower plant 1 or the water flow channel 3. Said second turbine 6 is arranged to be exposed to horizontally flowing water when the hydropower plant 1 is in operation. The phrase "arranged to be exposed to horizontally flowing water" as used in the description as well as in the appended claims, means that the second turbine 6 is located to recover the kinetic energy held by the water masses upstream, or more precisely at the inlet of the hydropower plant 1. In other words, the second turbine 6 is arranged to recover substantially horizontal kinetic energy.

The second turbine 6 is connected to a second generator 7 via power transmission means 8. In the embodiment shown, the power transmission means 8 consists of a turbine shaft 8 emanating from the second turbine 6 which, in the embodiment shown, transmits the second turbine 6 rotational movement to said second generator 7. Said second generator 7 is further connected in a conventional manner to suitable transformers and converters in order for the recovered electricity to obtain a suitable shape and strength for distribution.

Furthermore, said second turbine 6 may be equipped with a cooperating funnel 9, or the like, while forming a turbine module arranged to further increase the velocity of the water masses and thus the kinetic energy at the second turbine 6. The mouth and cross-sectional shape of the funnel 9 may have any suitable form for capturing and focusing the water masses, for example circular, rectangular, etc., where the cross-sectional area of the estuary is, for example, 10 square meters.

Preferably, all water masses are led via the second turbine 6 and then also pass the first turbine 2.

It should be pointed out that the hydropower plant 1 should only preferably be of the siphon type, however, this type is strongly preferred because the water masses, directly downstream of the second turbine 6, are continuously sucked away and thus can further enhance the flow through the second turbine 6. 550 010 Possible modifications of the invention The invention is not limited only to embodiments. Thus, the docking unit is modified in every way within the scope of those described above and shown in the drawings. can attach the requirements.

Both the first turbine and the second turbine can consist of one or more parallel turbine modules, which are for example arranged side by side in order to be able to utilize / extract the energy from the water masses in the most efficient way possible, for example when the water masses upstream of the hydropower plant have large lateral distribution.

It should be pointed out that the first generator belonging to the first turbine and the second generator belonging to the second turbine may be operatively connected to each other or even consist of one and the same generator.

In addition, the orientation of the second turbine and / or said funnel in space is not limited to that shown in Figure 2, but can also be positioned at an angle relative to the horizontal plane.

Claims (6)

10 15 20 25 30 35 530 010 8 Patent claims Hydropower plant, comprising a first turbine (2) connected to a first generator (4), which is located at a position in a water passage (3) located in the hydropower plant (1), and which is arranged to be exposed to vertical flowing water, flow channel characterized in that it also comprises a second turbine (6) connected to a second generator (7), which is located at a position upstream of said first turbine (2) in the vicinity of the inlet of the water flow channel (1), and which is arranged to be exposed to horizontally flowing water. Hydropower plant according to claim 1, characterized in that its water flow channel (3) consists of a siphon line extending from the inlet of the hydropower plant (1) to the outlet thereof, and in which said first turbine (2) is arranged. Hydroelectric power plant according to claim 1 or 2, characterized in that said second turbine (6) is equipped with a cooperating funnel (9). Hydroelectric power plant according to claim 3, characterized in that said funnel (9) has a rectangular cross section. Hydroelectric power plant according to any one of the preceding claims, characterized in that said second turbine (6) consists of a plurality of turbines operating in parallel. A method of extracting electricity by means of a hydropower plant (1), comprising the steps of placing a first turbine (2) connected to a first generator (4) at a position in a water flow channel (3) present in the hydropower plant (1). ) and exposing said first turbine to vertically flowing water, characterized in that the steps of placing a second turbine 530 010 (6) connected to a second generator (7) in the vicinity of the inlet of the water flow channel (1) and exposing said second turbine (6) for horizontally flowing water.