KR100814859B1 - Maintenance system of helical turbine - Google Patents

Abstract

A prefabricated helical turbine is provided to shorten working time and save maintenance cost by assembling a helical turbine and a housing, which form a pair, in plural by using a coupler and a connection member. A prefabricated helical turbine comprises a helical turbine(21) and a housing(11). The helical turbine has a plurality of blades at a rotating shaft(22) thereof to generate continuously rotational force. The housing supports the helical turbine while surrounding the helical turbine. A coupler connects a rotating shaft of the helical turbine with a rotating shaft of another helical turbine. A connection member connects the housing with another housing to support another helical turbine, which is connected with the helical turbine, while surrounding another helical turbine. The number of the helical turbines and the housings, which form a pair, is adjusted according to installation environments of the helical turbines.

Description

Prefab Helical Turbine {MAINTENANCE SYSTEM OF HELICAL TURBINE}

1 is a cross-sectional view showing a helical turbine generator of a conventional structure,

2 is a cross-sectional view showing a generator equipped with a prefabricated helical turbine according to an embodiment of the present invention;

3 is a perspective view of the helical turbine shown in FIG.

4 is an exploded perspective view illustrating the housing illustrated in FIG. 2;

5 to 10 is a state diagram showing a process in which the helical turbine is installed,

5 is a state in which the first housing is mounted,

6 is a state diagram showing a state in which the first housing is mounted,

7 is a state diagram showing a state in which the second housing is mounted,

8 is a state diagram showing a state in which the second helical turbine is mounted,

9 is a state diagram showing a state in which the third housing and the helical turbine is mounted,

10 is a state diagram showing a state in which the installation of the helical turbine is completed;

11 is a plan view of the brake member;

** Description of the symbols for the main parts of the drawings **

10 housing assembly 11 housing

20: helical turbine assembly 21: helical turbine

22: axis of rotation 25: coupler

The present invention relates to a prefabricated helical turbine, and more particularly, a state in which the helical turbine and the housing assembly are controlled by adjusting the number of the helical turbine and the housing paired according to the installation environment in which the helical turbine and the helical turbine are installed. It relates to a prefabricated helical turbine formed of a structure installed in the furnace frame to facilitate assembly and disassembly.

In general, a turbine refers to a machine or device that converts energy of a fluid such as water, gas, steam, etc. into useful mechanical work. The tidal power generation is used as a device for generating energy by using such a turbine.

Conventional tidal power generation is similar to the hydroelectric power generation method by installing tidal dams within the tidal tidal flats to block the movement of seawater, and then using the tidal level inside and outside tidal dams generated by tidal tidal flows. Do.

However, in order to drive tidal power generation, the use of potential energy is required, so a level difference over a certain height is required. In order to solve this problem, it is necessary to form a repellent, and thus there is a problem that entails environmental problems such as seawater contamination.

In order to solve this problem, a helical turbine has been developed and is in use. Helical turbines are devices designed by Professor Gorlov of Northeastern University in the United States to provide rotation for unidirectional as well as multidirectional flows of fluid. Such a helical turbine generator is to increase the rotation of the helical turbine 130 and the helical turbine 130, which is rotatably installed in the frame 120 installed inside the fluid as shown in Figure 1 to the speed required for power generation It consists of a speed increaser 105 and a generator for generating electricity by receiving the rotational speed of the speed increaser 106.

The helical turbine 130 has a rotation shaft 131 rotatably supported by the frame 120, a plurality of support members 132 protruding in a pair to radially layer on the rotation shaft 131, and layered It is connected to the end of each support member 132 and has a streamlined cross-sectional shape and consists of a blade 133 made of a helical shape twisted along the longitudinal direction of the rotating shaft 131.

However, since the plurality of blades 133 and the support member 132 are integrally mounted on one rotation shaft 131 of the conventional structure configured as described above, there is a difficulty in installation and any one of the blades ( 133) or failure of the support member 132 is difficult to disassemble. That is, the length of the rotary shaft 131 is difficult to secure a working space during assembly or disassembly, and if a failure occurs in any part, there is an inconvenience of replacing the whole.

In addition, when the helical turbine is installed in a state in which it is to be removed, the helical turbine is rotated by the flow of fluid during assembly or disassembly, so that the operation is difficult.

An object of the present invention devised in view of the above point is to provide a prefabricated helical turbine that can be easily assembled and disassembled helical turbine installed in the helical turbine generator.

Prefabricated helical turbine generator for achieving the object of the present invention as described above is a helical turbine formed with a plurality of blades on the rotating shaft to generate a continuous rotational force for one-way or multi-directional flow of fluid; A housing surrounding and supporting the helical turbine; A coupling member connecting another housing to the housing so as to surround and support the coupler connecting the rotation shaft of another helical turbine to the rotation shaft of the helical turbine and another helical turbine connected to the helical turbine; It characterized in that it is assembled and installed in the frame by adjusting the number of the helical turbine and the housing paired according to the installation environment in which the helical turbine is installed.

Hereinafter, with reference to the accompanying drawings, the helical turbine of the prefabricated preferred embodiment of the present invention in more detail as follows.

Figure 2 is a cross-sectional view showing a generator equipped with a prefabricated helical turbine is a preferred embodiment of the present invention, Figure 3 is a perspective view of the helical turbine shown in Figure 2, Figure 4 is an exploded housing shown in Figure 2 5 to 10 is a state diagram illustrating a process of installing a helical turbine, FIG. 5 is a state diagram in which the first housing is mounted, and FIG. 6 is a state diagram in which the first housing is mounted. 7 is a state diagram showing a state in which the second housing is mounted, FIG. 8 is a state diagram showing a state in which the second helical turbine is mounted, and FIG. 9 shows a state in which the third housing and the helical turbine are mounted. Fig. 10 is a state diagram showing a state where the installation of the helical turbine is completed, and Fig. 11 is a plan view showing the brake member.

As shown, a helical turbine generator equipped with a prefabricated helical turbine according to an embodiment of the present invention includes a frame 30 installed inside a fluid, a housing assembly 10 mounted on the frame 30, and the housing 10. The helical turbine assembly 20 rotatably supported by), the speed increaser 2 for increasing the rotation of the helical turbine assembly 20 to the speed required for power generation, and the rotation speed of the speed increaser 2 are received. It consists of a generator that generates electricity.

The helical turbine assembly 20 has a rotation shaft 22 having a predetermined length, a plurality of support members 23 protruding in pairs to radially layer on the rotation shaft 22, and ends of the support members 23. A helical turbine 21 having a streamlined cross-sectional shape and a blade 24 made of a helical shape twisted along the longitudinal direction of the rotational shaft 22 has a structure connected to a plurality of couplers 25. At this time, the number of helical turbines 21 connected by the coupler 25 is determined according to the installation environment or other requirements, and the rotating shaft 22 as a mechanism for connecting the coupler 25 to the ends of each rotary shaft 22 to each other. It is common to form a structure in which the bolt is fastened by fixing the end of the fixed state.

Although not shown, the helical turbine 21 has a plurality of auxiliary support members (not shown) that are shorter and staggered than the support members 23 in pairs to be radially layered on the rotation shaft 22, and an auxiliary support member (not shown). An auxiliary blade (not shown) which is connected to the end of the si) and has the same shape as the blade 24 may be further formed.

The housing assembly 10 protrudes from the bottom part 13 to form a circular wheel shape and a helical turbine 21 to which a radial bearing 12 supporting a rotating shaft is mounted at a central portion thereof. The housing 11, which is composed of a plurality of side pillars 14, has a structure in which a bolt, which is a connecting member, is fastened and stacked in a layered layer. At this time, the number of the housing 11 is determined according to the number of the helical turbine 21 is installed.

In addition, although the housing assembly 10 is shown to form a rectangle in the front projection in FIG. 2, preferably, the housing assembly 10 may have a trapezoidal shape in which the width thereof becomes narrower toward the lower side in the front projection. That is, although not shown, each housing 11 to be assembled is made of a trapezoid whose width becomes narrower toward the lower end, and the lower end surface of the housing 11 on which the upper end surface of the housing 11 located on the lower end is placed. It is preferable that the housing assembly 10, which is composed of the same structure as the overall assembly, has a trapezoidal shape in which the width thereof becomes narrower toward the lower end in front projection.

The frame 30 is a frame having a frame shape which is immersed in the fluid, and is perpendicular to the position where the housing assembly 10 is to be mounted so as to support the housing 11 constituting the housing assembly 10. A plurality of elastic members 31 having inner diameters corresponding to outer diameters of the housing 11 are mounted along the line. At the upper end of the frame 30, a fixing bracket 32 capable of temporarily fixing the upper end of the side pillar 14 at one side of the housing 11 is mounted. And the brake member 33 for temporarily fixing the rotation of the rotating shaft 22 during the operation is installed on the frame 30 so as to be located on the upper end of the fixing bracket (32).

The brake member 33 includes a first brake plate 34 having a semicircular friction groove 34a corresponding to the rotation shaft 22 in the center region and fixed to the frame 30, and corresponding to the rotation shaft 22 in the center region. The semi-circular friction groove 35a is formed and the second brake plate 35 assembled with the first brake plate 34, and the first brake plate 34 and the second brake plate 35 are friction grooves 34a, It consists of a pressing bolt 36 is fastened through so as to press the rotating shaft 22 fitted in the 35a).

Referring to the process of assembling the prefabricated helical turbine configured as described above are as follows.

After inserting the housing 11 into the fixing bracket 32 installed in the frame 30, as shown in Figure 5, the upper end of the side pillar portion 14 is installed so as to be temporarily fixed to the fixing bracket (32).

6, after inserting the helical turbine 21 into the housing 11 so that the end of the rotary shaft 22 is inserted into the radial bearing 12, the rotary shaft 22 is inserted into the brake member 33. To prevent it from rotating.

As shown in FIG. 7, the second housing 11 is placed on the first installed housing 11, and the second housing 11 and the first housing 11 are bolted together. That is, a fastening hole (not shown) is formed in the bottom portion 13 of the second housing 11, and a female screw coincides with the fastening hole in the side column 14 of the first housing 11 to fasten the bolt. Made of structure.

As shown in FIG. 8, the second helical turbine 21 is inserted into the second housing such that the end of the rotation shaft 22 of the second helical turbine 21 is inserted into the radial bearing 12 of the second installed housing 11. (11) Insert it inside. At this time, it is connected to each other by the coupler 25 of the first rotary shaft 11 and the second rotary shaft (11). In this state, the brake member 33 which fixes the rotating shaft 11 is loosened, and the housing 11 and the helical turbine 21 are lowered using a crane.

As shown in FIG. 9, the side pillars 14 of the second housing 11 are fixed to the fixing bracket 33, and the brake member 33 is operated to fix the rotation shaft 11 so as not to rotate. The third housing 11 in the second housing 11 and the helical turbine 21 in the same way as the first housing 11 and the helical turbine 21 were installed in the first housing 11 and the helical turbine 21. And a helical turbine 21 are installed.

In this state, if the housing 11 and the helical turbine 21 are to be installed continuously, the fourth, fifth, and continuous installations may be performed in the same repetition as above while descending using a crane.

As shown in FIG. 10, the rotating shaft 22 of the housing 11 and the helical turbine 21 may be mounted on the frame 30 when the third housing 11 and the helical turbine 21 are installed. The connecting pillars 14a and 22a are installed to extend and secure to the upper end. The rotating shaft 22 and the connecting column 22a are connected by using the coupler 25, and the side column 14 and the connecting column 14a of the housing 11 are connected by fastening bolts.

Although the housing assembly 10 may be configured to have an overall rectangular shape in front projection as shown in FIG. 2, although not shown, the housing assembly 10 is formed in an overall trapezoidal shape in front projection to lower the housing assembly 10. At the same time it is preferably made of a structure that is seated on the elastic member 31 provided in the frame (30).

Disassembly of the housing assembly 10 and the helical turbine assembly 20, the assembly is completed through the above process may be performed in the reverse order of the installation process.

As described above, the assembled helical turbine according to the present invention has a structure in which a plurality of helical turbines 21 and a housing 11 in which the helical turbine assembly 20 and the housing assembly 10 are paired are assembled. It is easy and less constrained by the installation space.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the prefabricated helical turbine according to the preferred embodiment of the present invention is configured such that the helical turbine and the housing are paired, and the helical turbine and the housing are formed in a structure capable of assembling a plurality of pairs using the coupler and the connecting member. By doing so, assembling and disassembling are easily performed, thereby reducing work time and reducing maintenance costs.

Claims (11)

A helical turbine having a plurality of blades formed on a rotating shaft to generate continuous rotational force with respect to one-way or multi-directional flow of the fluid; A housing surrounding and supporting the helical turbine; A coupler connecting a rotational shaft of another helical turbine to a rotational shaft of the helical turbine; And A connecting member connecting another housing to the housing to support and support another helical turbine connected to the helical turbine; Including Prefabricated helical turbine, characterized in that the assembly is installed by adjusting the number of the helical turbine and the housing paired according to the installation environment in which the helical turbine is installed and installed in the frame. The helical turbine of claim 1, wherein A plurality of support members protruding in pairs to radially layer in the rotation axis; And A blade connected to an end of the support member and having a streamlined cross-sectional shape and helical shape twisted along a longitudinal direction of the rotation shaft; Prefabricated helical turbine comprising a. The helical turbine of claim 2, wherein A plurality of auxiliary supporting members protruding shorter and staggered from each other in pairs to form a radial layer on the rotation shaft; And An auxiliary blade connected to an end of the auxiliary supporting member and having a streamlined cross-sectional shape and helical shape twisted along a longitudinal direction of the rotation shaft; Prefabricated helical turbine, characterized in that it further comprises. The method of claim 1, wherein the housing A bottom portion forming a circular wheel shape in which a radial bearing supporting the rotating shaft is mounted at a center portion thereof; And A plurality of side pillars protruding from the bottom portion to surround the helical turbine; Prefabricated helical turbine comprising a. The method of claim 4, wherein when another housing is connected to the housing, The connecting member is a prefabricated helical turbine, characterized in that consisting of a bolt on which the bottom of the other housing is mounted on the top of the side pillar. The method of claim 4, wherein when another housing is connected to the housing, Prefabricated helical turbine comprising a trapezoidal shape when the front projection is made of a shape that becomes narrower gradually toward the lower direction from the housing mounted on the top. The method of claim 6, wherein the frame To support the housing Prefabricated helical turbine, characterized in that the center point is located on the same vertical line and a plurality of elastic members having an inner diameter corresponding to the outer diameter of the housing. 8. The frame of claim 1, wherein the frame comprises: Prefabricated helical turbine, characterized in that the fixing bracket is mounted to temporarily fix the top of one side of the housing. The method of claim 8, wherein the frame Prefabricated helical turbine, characterized in that for mounting the brake member to temporarily fix the rotating shaft to prevent rotation of the rotating shaft. 8. The frame of claim 1, wherein the frame comprises: Prefabricated helical turbine, characterized in that for mounting the brake member to temporarily fix the rotating shaft to prevent rotation of the rotating shaft. The method of claim 10, wherein the brake member A first brake plate having a semicircular friction groove formed in a central region corresponding to the rotating shaft and fixed to the frame; A second brake plate having a semicircular friction groove formed in a central region corresponding to the rotating shaft; And A pressure bolt fastened through the first brake plate and the second brake plate so that the first brake plate and the second brake plate pressurize the rotating shaft fitted into the friction groove; Prefabricated helical turbine comprising a.

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