KR20120105719A - Model test system for tidal current turbine - Google Patents

Abstract

PURPOSE: A system for testing a sample of a tidal wave generating turbine is provided to easily control a moving speed of a towing carriage by controlling a motor so that a performance analysis of a tidal wave generating turbine with respect to various velocities can be rapidly performed. CONSTITUTION: A system for testing a sample of a tidal wave generating turbine comprises a towing tank(100), a towing carriage(200), a vertical rotating shaft(310), a sample turbine(300), and a small generator(400). The towing carriage is horizontally moved along above a water surface of the towing tank. The vertical rotating shaft is joined to the lower part of the towing carriage. The sample turbine is joined to the vertical rotating shaft, thereby being arranged under the water surface of the towing tank. The sample turbine is rotated by rubbing with the water when the towing carriage is horizontally moved. The small generator is joined to the vertical rotating shaft, thereby generating power by receiving the torque of the sample turbine.

Description

MODEL TEST SYSTEM FOR TIDAL CURRENT TURBINE

The present invention relates to a model test system for a tidal power turbine, and more particularly, to a model test system for a tidal power turbine to perform the performance test of the tidal power turbine for various flow rates in the towing tank.

Algae power generation is a method of generating electricity by turning a turbine installed in the sea using ocean currents without installing dams or breakwaters in the sea where fast seawater flows. There is no need to construct a separate breakwater on the coast like tidal power generation. This is less expensive than tidal power and is considered more environmentally friendly. Therefore, as the topic of new and renewable energy has increased recently, the development of algae has attracted much attention.

Turbine used in the tidal power generation is a major device that primarily converts the kinetic energy of the tidal current, which has a great influence on the power generation efficiency and power generation, so the performance analysis is very important. In general, the performance analysis of tidal power turbines is performed in two ways: model test and computer simulation. Among them, the model test is to check the rotation and output of the model turbine by fixing the miniature model of the turbine in the circulating tank and sending the water flow at a constant flow rate. In a way.

However, in the conventional model experiment conducted in the circulating tank, the size of the circulating tank is limited so that the size of the model turbine cannot be large enough, and the flow rate range that can be provided is limited, so that the actual characteristics of the turbine are sufficiently reflected. There was a problem that can not.

The present invention to solve the above problems the towing tank; A towing tank moving horizontally along the water surface of the towing tank; A vertical rotation shaft coupled to the lower surface of the towing tank; A model turbine coupled to a lower end of the vertical rotation shaft and positioned below the water surface of the towing tank, and rotating by friction with water during horizontal movement of the towing tank; And, coupled to the vertical axis of rotation provides a model test system of a tidal power turbine comprising a small generator for generating power by receiving the rotational force of the model turbine.

The model test system of the tidal power turbine according to the present invention allows the model turbine experiment to be carried out in a relatively wide towing tank rather than a circulating tank. Therefore, the size of the model turbine can be increased as much as possible, enabling accurate experiments closer to actual physics.

In addition, the model test system of the tidal power turbine according to the present invention can quickly adjust the moving speed of the towing tank by controlling the motor to quickly perform the performance analysis of the tidal power turbine for various flow rates. In particular, since it is possible to change the speed of the towing tank at any time by controlling the motor while the towing tank is horizontally moved, an experiment in consideration of an environment in which the flow velocity changes very much becomes possible.

In addition, the model test system of the tidal power turbine according to the present invention enables the experiment reflecting the actual marine environment using the multi-directional wave generator sowing installed in the towing tank.

1 is a view showing a schematic structure of a model test system of a tidal current turbine according to the present invention.

Hereinafter, preferred embodiments of the present invention in which the above object can be specifically realized are described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and additional description thereof will be omitted in the following.

1 is a view showing a schematic structure of a model test system of a tidal current turbine according to the present invention.

As shown in FIG. 1, a model test system of a tidal current turbine according to the present invention includes a towing tank 100, a towing tank 200, a model turbine 300, and a small generator 400.

The towing tank 100 evaluates the hydrodynamic performance of the ship such as resistance propulsion and speed performance of the model ship, flow measurement and observation around the hull, motion and acceleration performance, steering performance, propeller performance, wave load measurement, etc. It is a design facility with multi-directional wave generators (not shown) that can realize actual sea conditions, and a depth of 8m depth for testing deep sea structures.

The towing tank 200 is installed to move horizontally on the water surface of the towing tank 100, for this purpose, although not shown, guide rails are installed on both left and right sides of the towing tank 100, and The lower surface is provided with a guide roller for sliding along the guide rail. Therefore, when a driving force is applied to the towing tank 200 by a motor or the like, the guide roller moves along the guide rail so that the towing tank 200 horizontally moves on the water surface of the towing tank 100. Although the maximum speed of the towing tank 200 is about 7 m / s at present, research is being conducted to speed up the towing tank so that model experiments on various types of high-speed ships can be performed.

The model turbine 300 is a model experiment in which the actual tidal power turbine is reduced to a certain ratio, and is coupled to a vertical rotation shaft 500 installed on the lower surface of the towing tank 200 to friction with water during horizontal movement of the towing tank 200. It is configured to rotate by. Specifically, the model turbine 300 is coupled to the lower end of the vertical axis of rotation 500 as shown is located below the water surface of the towing tank 100, accordingly, when the towing tank 200 starts horizontal movement It naturally rotates by friction with water.

The model turbine 300 includes a horizontal rotary shaft 310 coupled to the vertical rotary shaft 500, a blade 320 formed on a front outer surface of the horizontal rotary shaft 310, and a rear end outer surface of the horizontal rotary shaft 310. It is made of a housing 330 wrapped around the protection. Therefore, when the towing tank 200 starts horizontal movement, the friction force is applied to the blade 320 of the model turbine 300 so that the horizontal rotating shaft 310 starts to rotate in the housing 330.

Here, the rotational force of the horizontal rotating shaft 310 is transmitted to the vertical rotating shaft 500, for this purpose, a pair of bevel gears 600 are installed at the coupling portion of the horizontal rotating shaft 310 and the vertical rotating shaft 500. The bevel gear 600 is manufactured in a conical shape, and a pair is engaged with each other to transfer the rotational force of the horizontal rotating shaft 310 to the vertical rotating shaft 500. Types of the bevel gear 600 include a straight bevel gear (straight bevel gear), a curved bevel gear (spiral bevel gear), a zero roll bevel gear (zerol bevel gear).

Reference numeral 510 denotes an outer strut fixed to the lower surface of the towing tank 200, and the outer strut 510 surrounds and protects the vertical rotating shaft 500. As described above, the vertical rotation shaft 500 is installed on the lower surface of the towing tank 200 and is located below the surface of the water to prevent contact with water and directly receive the pressure applied during horizontal movement of the towing tank 200. 510 is preferably rotatably installed inside.

Meanwhile, bearings 340 and 520 supporting the horizontal rotating shaft 310 and the vertical rotating shaft 500 are respectively installed in the housing 330 and the outer strut 510. The bearings 340 and 520 contact the outer surfaces of the horizontal rotating shaft 310 and the vertical rotating shaft 500 to facilitate smooth rotation of the horizontal rotating shaft 310 and the vertical rotating shaft 500.

The small generator 400 is installed on the upper surface of the towing tank 200, and generates electricity using the rotational force of the model turbine 300 is coupled to the vertical rotation shaft 500 and transmitted through the vertical rotation shaft 500. To this end, a pair of bevel gears 700 are installed on the coupling portion of the vertical rotation shaft 500 and the small generator 400 to transmit the rotational force of the vertical rotation shaft 500 to the rotation shaft 410 of the small generator 400. Therefore, when the towing tank 200 starts to move horizontally and the horizontal rotating shaft 310 starts to rotate together with the blade 320, the rotational force of the horizontal rotating shaft 310 moves the vertical rotating shaft 500 by the bevel gears 600 and 700. It is transmitted to the rotating shaft 410 of the small generator 400 through, the power generation is made in the small generator 400.

Since the power generation amount of the small generator 400 represents the power generation performance of the model turbine 300, the performance of the model turbine 300 under test can be confirmed through the power generation amount of the small generator 400. Of course, instead of simply experimenting with the power generation performance of the model turbine 300, a high resolution camera (not shown) and an Nd / Yag laser light source (not shown) are installed inside the towing tank 100 as necessary. It is also possible to proceed with the experiment to measure the flow field around the model turbine 300 during the horizontal movement of the 200.

As described above, in the model test system of the tidal power turbine according to the present invention, the model turbine 300 is installed on the lower surface of the towing tank 200 moving horizontally, so that the tidal power turbine is installed in the relatively wide towing tank 100 instead of the circulating water tank. Allow performance tests to be performed. Therefore, by increasing the size of the model turbine 300 as much as possible can proceed to the exact experiment closer to the actual physical phenomenon.

In addition, since the moving speed of the towing tank 200 can be easily adjusted by controlling the motor, performance analysis of the tidal current turbine for various flow rates can be quickly performed. In order to proceed with the performance analysis of the turbine for the various flow rates in the circulating water tank, it is necessary to change the flow rate of the water flowing into the turbine one by one. By adjusting the moving speed, the same effect as changing the flow velocity of water flowing to the model turbine 300 may occur, so that the experiment may proceed quickly. In particular, it is possible to change the speed of the towing tank 200 at any time by controlling the motor during the horizontal movement of the towing tank 200, so that an experiment in consideration of an environment in which the flow velocity changes very much becomes possible.

Furthermore, as described above, the towing tank 100 is equipped with a multi-directional wave generator so as to implement an actual sea state, so that experiments may be made in consideration of various actual sea environments.

The present invention described in detail above is not limited to the above-described range, and those of ordinary skill in the art can easily change or replace the scope of the present invention, as well as equivalents thereof. Also included within the scope of the present invention.

100: towing tank 200: towing tank
300: model turbine 310: horizontal axis of rotation
320: blade 330: housing
340,520: bearing 400: small generator
410: generator axis of rotation 500: vertical axis of rotation
510: external strut 600,700: bevel gear

Claims (6)

Towing tank;
A towing tank moving horizontally along the water surface of the towing tank;
A vertical rotation shaft coupled to the lower surface of the towing tank;
A model turbine coupled to a lower end of the vertical rotation shaft and positioned below the water surface of the towing tank, and rotating by friction with water during horizontal movement of the towing tank; And,
The model experiment system of the tidal-generation turbine comprising a small generator coupled to the vertical rotation shaft for generating power by receiving the rotational force of the model turbine. The method according to claim 1,
The model turbine includes a horizontal rotary shaft coupled to the vertical rotary shaft, a blade formed on the outer surface of the front end of the horizontal rotary shaft, the model generator system of a tidal current turbine comprising a housing surrounding the outer surface of the rear end of the horizontal rotary shaft. The method of claim 2,
And a pair of bevel gears for transmitting the rotational force of the horizontal rotating shaft to the vertical rotating shaft at a coupling portion of the horizontal rotating shaft and the vertical rotating shaft. The method of claim 2,
The model experiment system of the tidal power turbine, characterized in that the lower side of the towing tank is fixed to the outer strut surrounding the vertical axis of rotation fixedly installed. 5. The method of claim 4,
A model test system for a tidal current turbine, characterized in that bearings for supporting a horizontal rotating shaft and a vertical rotating shaft are installed in the housing and the outer strut, respectively. The method according to claim 1,
The pair of bevel gears for transmitting the rotational force of the vertical rotary shaft to the rotary shaft of the small generator is installed in the coupling portion of the vertical rotary shaft and the small generator is a model test system of a tidal power turbine.

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