RU189385U1 - UNDERWATER FLOATING HYDROELECTRIC POWER PLANT - Google Patents

Abstract

The utility model relates to hydropower, in particular to the design of devices for generating electricity due to the energy of the hydraulic flow of the river. Improving the efficiency and stability of the operation of a floating hydroelectric dam, with varying loads on the turbine due to the possibility of self-regulation of the depth of its immersion in the water flow, is achieved in that the floating hydroelectric station containing anchored floating base in the form of a catamaran, is installed At least one hydraulic turbine containing a rotor, the cavity of which is filled with material whose density is less water density, provided outside with blades, while the rotor shaft of the turbine is kinematically connected with the electric generator and installed on supports, the blades of the turbine have the form of a parabola fragment, the part of the blade extending from the base, and the rotor shaft supports of the turbine are movable along height relative to the floating base.

Description

The utility model relates to hydropower, in particular to the design of devices for generating electricity due to the energy of the hydraulic flow of the river.

Known dam-free floating hydroelectric power station (hereinafter - BPHPP), containing a floating base moored using a cable system in the form of a catamaran, on which at least one hydro turbine is installed, containing a rotor, fitted with blades outside its hull, and the rotor shaft of the hydro turbine is kinematically connected with electric generator and installed on supports (see RF patent for invention №2474724, IPC F03B 7/00, publ. 10.02.2013). The disadvantages of the known device can be attributed to the lack of efficiency in the operation of BPHPP with varying values of the load on the turbine.

The closest in technical essence to the present invention is BPGES containing a floating base in the form of a catamaran anchored using a cable system, on which at least one hydraulic turbine is installed, containing a rotor, the body cavity of which is filled with a material whose density is less than the density of water provided outside blades, while the rotor shaft of the turbine is kinematically connected with an electric generator and installed on supports (see RF patent for invention №2607142, IPC F03B 17/06, publ. 12.10.2015). The disadvantages of the known device can also be attributed to the lack of efficiency in the operation of BPHPP with varying values of the load on the turbine.

The proposed utility model is aimed at solving a technical problem and achieving a technical result consisting in increasing the efficiency and stability of the BPHPs operation with varying load on the turbine due to the possibility of self-regulation of the depth of its immersion in the water flow.

This technical result is achieved by the fact that in BPHPP containing a floating base anchored using a cable system in the form of a catamaran on which at least one hydraulic turbine is installed, containing a rotor, the body cavity of which is filled with a material whose density is less than the density of water provided outside blades, while the rotor shaft of the turbine is kinematically connected with the electric generator and is mounted on supports, the blades of the hydraulic turbine have the shape of a parabola fragment, the part of which I extend from the base the peripheral part of the blade, and the supports of the rotor shaft of the turbine are made with the possibility of their movement along the height relative to the floating base.

The execution of turbine blades having the shape of a parabola fragment, the part of which extends from the base is the peripheral part of the blade, allows self-regulation of the immersion depth of the turbine in the water flow when the load on the turbine changes. For example, increasing the load increases the moment of resistance to rotation of the turbine rotor. This increases the force acting from the water flow on the curved blades of the turbine, and downward its vertical component, due to the curvilinear shape of the blade, tends to drown the turbine rotor. As shown by our experimental studies (the results are given below), in order to have the most effective impact on the hydro turbine in the direction of its immersion, it is advisable that the curvature of the blade increases towards its periphery rather than remain constant as in the prototype. This condition corresponds to the geometry of the parabola, which is proposed for the shape of the turbine blade. In this case, the downward-directed vertical component will take place in almost all turbine blades in the water flow, and as the load increases, the rotor will sink more and more into the water flow and, accordingly, the larger surface of the blades will be under the influence of the water flow. Thus, there is an automatic self-regulation of the immersion rate of the turbine rotor into the water flow until the vertical component of the impact on the blades and the upward direction is balanced by the ascent force of the rotor, the cavity of which is filled with a material whose density is less than the density of water. When changing the loads on the rotor of the turbine, it will sink or float in the water flow, the surface of the blades under the influence of the water flow, and accordingly, the power of the water turbine will change. In view of this, BPGESM will function efficiently and stably with changing values of the load on the hydro turbine.

In this case, it is obvious that in the case of fixing the rotor of the turbine on a support that is installed without the possibility of changing its height above the floating base, the rotor can only be immersed in the water flow together with the floating base, which substantially levels the effect described above due to the high immersion resistance rotor. Supporting the rotor shaft of the turbine with the possibility of their movement along the height relative to the floating base allows eliminating the influence of this floating base on the rotor movement and facilitates the efficient and stable functioning of the HPPG with the variable values of the load on the turbine due to the possibility of self-regulation of the depth of its immersion into the water flow.

Thus, the simultaneous and joint use of the features of the claimed utility model, characterizing the shape of the blade and the execution of the support of the shaft of the turbine, allows to obtain the above technical result.

FIG. 1 shows a side view of the BPHPP with one turbine; in fig. 2 is a top view of the BPGES with two hydro turbines; in fig. 3 is a top view of the BPGES with four hydro turbines (festoon); in fig. 4 is a schematic depiction of a cross section of a rotor of a turbine with blades; in fig. 5 is a schematic depiction of a longitudinal section of a turbine rotor with vanes; in fig. 6 is a drawing explaining the execution of a rotor blade in the form of a parabola fragment; in fig. 7 is an experimental graph of the power of the turbine as a function of the speed of the water flow (obtained using the model of a hydro turbine) when the blade is in the form of a circular arc (as in the prototype); FIG. 8 is an experimental graph of the power of the turbine as a function of the speed of the water flow (obtained using the model of a hydro turbine) when the blade is in the form of a parabola fragment.

БПГЭС contains a floating base 2 in the form of a catamaran anchored with the use of cable 1 system, on which at least one hydraulic turbine is installed, containing rotor 3, the casing 4 of which is filled with material whose density is less than the density of water. This can be a hollow rotor (airtight) simply only with an air cavity 4 of the body or a rotor whose cavity 4 is filled, for example, with foam plastic 5. The rotor 3 is provided outside the body with blades 6 that have the shape of a parabola fragment shown in FIG. 6 solid fat line. At the same time, the part extending from the base 7 of the parabola is the peripheral part of the blade 6, and the blade 6 itself is attached to the rotor case 3 by the opposite part. The rotor 3 with blades 6 on the sides is limited to disks 8. The rotor shaft 9 of the turbine is kinematically connected to an electric generator 10 and mounted on supports 11, which are configured to move along the height relative to the floating base 2. Such supports can be made, for example, on the basis of conventional shock absorbers, including those with adjustable stiffness or similar to the technical solution set forth in the RF patent for useful model No. 99078 in the form of supports moving along vertical columns. The generator 10 is provided with an electric cable (not shown) connecting it to an electrical consumer. Also BPGES can be equipped with partitions 12, forming a narrowing channel at the entrance, and guiding with acceleration the water flow to the hydro turbine.

The proposed BPHPP works as follows.

When installing BPGES on the river, the place convenient for its placement is chosen, and the floating base 2 with the units installed on it is locked in this place with the help of anchors and a system of 1 cables. In this case, the rotor 3 floats in the water flow in such a way that its axis is above the waterline. The water flow with the help of partitions 12 is accelerated, acts on the blades 6 of the turbine rotor, forcing it to rotate. The shaft of the electric generator 10 connected directly or through a gearbox (not shown) also rotates and the electric generator 10 generates electricity, which is delivered to the consumer via an electric cable.

When you change the load on the turbine, for example, when it increases, the moment of resistance to rotation of the rotor 3 of the turbine increases. This increases the force acting from the water flow on the curved blades 6 of the rotor of the turbine, and downward its vertical component, due to the curvilinear shape of the blades, seeks to drown the rotor of the turbine. With increasing load, the rotor 3 will be increasingly submerged in the water flow and, accordingly, the larger surface of the blades will be under the influence of the water flow. Thus, there is an automatic self-regulation of the immersion of the rotor 3 of the turbine into the water flow until the vertical component of the impact on the blades 6 is down and directed upward by the Archimedean force of ascent of the rotor 3, the body cavity of which is filled with material whose density is less than the density of water. When changing the loads on the rotor 3 of the turbine, it will sink or float in the water flow, the surface of the blades under the influence of the water flow, and, accordingly, the power of the water turbine will change. In view of this, BPGES will function efficiently and stably with changing values of the load on the hydro turbine.

BPHPP can be formed with different layouts of individual hydro turbines, as shown in FIG. 2 and FIG. 3, which is known per se and is not the subject of the claimed utility model, and with any arrangement each individual hydro turbine will function in the manner described above.

The proposed utility model provides high efficiency and stability of the BPGES operation with varying values of the load on the turbine due to the possibility of self-regulation of the depth of its immersion in the water flow.

Claims (1)

A floating floating hydroelectric station containing a floating base in the form of a catamaran anchored using a cable system, on which at least one hydraulic turbine is installed, containing a rotor, the body cavity of which is filled with a material whose density is less than the density of water and fitted with blades outside, the rotor shaft turbine kinematically connected with the generator and installed on supports, characterized in that the blades of the turbine are in the form of a fragment of a parabola, part extending from the base to Torah a peripheral portion of the blade, and the hydraulic turbine rotor shaft support configured to move by their height relative to the floating base.

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