KR102341662B1 - Method and assembly aid device for assembling a guide vane of water turbine - Google Patents

Abstract

The present invention relates to an auxiliary apparatus for assembling a guide vane for a water wheel and a method for assembling the guide vane for the water wheel. The auxiliary apparatus for assembling the guide vane for the water wheel according to the present invention comprises: a first measuring device provided on one side of a guide vane arm cover and measuring a separation distance between the guide vane arm cover and the guide vane; a second measuring device provided on one side of a top cover and measuring the separation distance between the top cover and the guide vane; a third measuring device provided on one side of a bottom ring and measuring the separation distance between the bottom ring and the guide vane; and a data management device for managing measurement values through the first measuring device, the second measuring device, and the third measuring device. The method for assembling the guide vane for the water wheel according to the present invention comprises: a first measuring step of measuring the separation distance between the top cover and the guide vane with the second measuring device; a second measuring step of measuring the separation distance between the bottom ring and the guide vane with the third measuring device; a third measuring step of measuring the separation distance between the guide vane arm cover and the guide vane with the first measuring device; a reprocessing step of re-processing the guide vane arm cover using the measurement value measured through the third measuring step; and an assembly step of assembling the reprocessed guide vane arm cover through the reprocessing step. According to this invention, while a gap between the guide vane, the bottom ring, and the top cover is properly adjusted, the guide vane and the guide vane arm cover can come into close contact, so efficiency of aberration can be guaranteed.

Description

TECHNICAL FIELD [0002] Method and assembly aid device for assembling a guide vane of water turbine

The present invention relates to an auxiliary device for assembling a guide vane for a water wheel and a method for assembling a guide vane for a water wheel. The present invention relates to an auxiliary device for assembling a guide vane for a water wheel and a method for assembling a guide vane for a water wheel so that the efficiency of the water wheel can be increased.

In general, a water wheel generator includes a water wheel that obtains motive power using water energy and a generator that converts mechanical energy obtained through the water wheel into electrical energy. say so

Here, the water wheel is divided into a buried part and an assembly part, and the buried part is installed to be connected to the dam structure for the purpose of suppressing vibration generation and maintaining strength.

Such a buried portion is composed of a spiral casing including a stay ring, a discharge ring, a draft tube, and the like.

As such a buried part is installed to be connected to the dam structure, it is almost impossible to change the matters applied at the time of initial construction.

On the other hand, the assembly part includes all equipment connected to the moving part that rotates in the water turbine generator or has an opening/closing function, and in the case of medium and large hydroelectric power plants, the main components of the water turbine are runners, guide vanes, These include a top cover, a bottom ring, and a turbine shaft.

And, as the building is designed in consideration of the disassembly of the assembly part during the construction of the power plant, the assembly part is installed so that it can be withdrawn to the outside when the rotor of the generator is disassembled.

That is, the assembly unit is configured to be replaced as necessary along with periodic inspection.

In this regard, in Korean Patent No. 10-1789308, it is intended to facilitate the inspection and maintenance of the turbine by developing a turbine shaft lifting device for a water turbine generator capable of safely separating the generator shaft and the turbine shaft.

However, recently, due to the influence of many environmental changes, the operating conditions of the water turbine generator are often changed as the meteorological conditions in the region where the hydroelectric power plant is operated are much different from the initial design stage.

That is, the drop and discharge amount for the operation of the dam can be changed due to various environmental changes including precipitation. changes, and this leads to a decrease in the amount of power generation, resulting in huge losses.

Korean Registered Patent No. 10-1789308

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, so that the guide vane and the guide vane arm cover can be in close contact while appropriately adjusting the gap between the guide vane and the bottom ring and the top cover. An object of the present invention is to provide an auxiliary apparatus for assembling a guide vane of a water wheel and a method for assembling a guide vane of a water wheel, which can increase the efficiency of the water wheel.

According to the feature of the guide vane assembly auxiliary device for a water wheel according to the present invention for achieving the above object, the first measurement is provided on one side of the guide vane arm cover and measures the distance between the guide vane arm cover and the guide vane. A device, a second measuring device provided on one side of the top cover for measuring the distance between the top cover and the guide vanes, and a third measuring device provided on one side of the bottom ring for measuring the distance between the bottom ring and the guide vanes, , characterized in that it is configured to include a data management device for managing the measurement values through the first measuring instrument, the second measuring instrument, and the third measuring instrument.

An insertion hole into which at least a portion of the first measuring device is inserted is formed at one side of the guide vane arm cover.

The first measuring device, the second measuring device, and the third measuring device are magnetically detachable.

According to the characteristics of the method for assembling the guide vane of the water wheel according to the present invention for achieving the above object, the first measuring step of measuring the separation distance between the top cover and the guide vane with a second measuring device, and the third measuring device A second measurement step of measuring the separation distance between the bottom ring and the guide vane with a furnace, a third measurement step of measuring the separation distance between the guide vane arm cover and the guide vane with the first measuring instrument, and the third measurement step It is characterized in that it comprises a re-processing step of re-processing the guide vane arm cover using the measured value, and an assembling step of assembling the re-processed guide vane arm cover through the re-processing step.

The third measuring step is performed after making the measured value obtained through the first measuring step and the measured value obtained through the second measuring step have uniform values.

According to the present invention, the apparatus for assembling the guide vane of a water wheel and the method of assembling the guide vane of the water wheel according to the present invention have the following effects.

In the present invention, since the separation distance between the guide vane and the bottom ring and the top cover can be precisely adjusted, the amount of leakage can be optimally controlled, thereby maximizing the efficiency of the aberration.

In the present invention, as the data management device is provided, the measurement data is managed systematically, thereby minimizing the time loss in adjusting the separation distance.

1 is a configuration diagram showing a configuration of a preferred embodiment of a guide vane assembly auxiliary device for a water wheel according to the present invention;
2 is an enlarged view showing the main part of the first measuring step constituting a preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention;
3 is an enlarged view showing the main part of the second measuring step constituting a preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention;
4 is an enlarged view showing the main part of the process of performing the third measuring step constituting the preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention;
5 is a front view showing the guide vane arm cover further processed through the re-processing step constituting a preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention;
6 is an enlarged view showing the main part of the assembly step constituting the preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention;

First, changes in the drop applied to the aberration and flow rate are required according to changes in the environment, and the power generation efficiency reflected in the aberration in the initial design stage changes, which leads to a decrease in the amount of power generation, resulting in huge losses.

In order to solve this problem, by replacing the assembly parts except for the materials of the existing buried part and recrystallizing the specifications of the aberration suitable for the changed environmental conditions, it is possible to obtain an improved power generation system close to the amount of power generated during the initial design.

In other words, in the case of a generator, if the replacement of many auxiliary facilities including transmission and substation facilities is carried out, the cost increases. Therefore, it is suggested as the best way to improve the performance by redesigning the water wheel unit while using it as it is.

In the above case, the redesign of the assembly part should be carried out in consideration of the buried part of the existing equipment and the fastening method, and in the Francis water wheel, the top cover, the spiral casing, and the bottom ring are mainly used. The connections between the spiral casing, guide vane and top cover, and guide vane and bottom ring are important.

In particular, a guide vane that controls the flow of running water on the flow path connected to the runner of the water wheel at the upper part of the dam is very important because it is directly related to the energy recovery rate. Here, the energy recovery rate refers to the efficiency of the aberration.

That is, when the amount of water leaking due to a gap between the guide vane and the top cover and the bottom ring is large, the power generation output is decreased.

In addition, if the gap between the guide vane and the top cover and the bottom ring is too small, the guide vane may be caught under the influence of foreign substances contained in water. .

Therefore, the gap between the guide vane and the top cover and the bottom ring should be properly maintained, and the present invention provides an inspection device for properly adjusting the gap of the guide vane 30 and It relates to the assembly method.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of an auxiliary apparatus for assembling a guide vane of a water wheel according to the present invention will be described with reference to the drawings.

As shown in FIGS. 1 to 6 , an embodiment of a guide vane assembly auxiliary apparatus for a water wheel and a method for assembling a guide vane of a water wheel according to the present invention are shown.

That is, FIG. 1 is a block diagram showing the configuration of a preferred embodiment of the apparatus for assembling the guide vane of the water wheel according to the present invention, and FIG. 2 is the preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention An enlarged view of the main part showing the process of performing the first measuring step is shown, and FIG. 3 is an enlarged view of the main part showing the process of performing the second measuring step constituting a preferred embodiment of the method for assembling the guide vane of the aberration according to the present invention 4 is an enlarged view showing the process of performing the third measuring step constituting a preferred embodiment of the method for assembling the guide vane of the water wheel according to the present invention, and FIG. 5 is the water wheel according to the present invention A front view showing the guide vane female cover further processed through the re-processing step constituting a preferred embodiment of the guide vane assembly method is shown, and in FIG. 6, a preferred embodiment of the guide vane assembly method of the water wheel according to the present invention is shown An enlarged view of the main part showing the process of performing the assembly step is shown.

As shown in these drawings, the guide vane assembly auxiliary device for the water wheel according to the present invention is provided on one side of the guide vane arm cover 10 and measures the separation distance between the guide vane arm cover 10 and the guide vane 30 . A first measuring device 50 that is provided on one side of the top cover 20 and a second measuring device 60 for measuring the separation distance between the top cover 20 and the guide vane 30, and a bottom ring 40 ) provided on one side of the third measuring device 70 for measuring the separation distance between the bottom ring 40 and the guide vane 30, the first measuring device 50, the second measuring device 60, the second 3 It is characterized in that it is configured to include a data management device 80 for managing the measurement value through the measurement device (70).

The guide vane arm cover 10 is provided with a first measuring device 50 .

The first measuring device 50 is provided at the upper end of the guide vane arm cover 10 , and is for measuring the separation distance between the lower end of the guide vane arm cover 10 and the upper end of the guide vane 30 shaft.

Here, the guide vane 30 includes a shaft forming an axis and a blade corresponding to the blade.

On the other hand, at one side of the guide vane arm cover 10, an insertion hole 11 into which at least a portion of the first measuring device 50 is inserted is formed.

The insertion hole 11 is formed to penetrate from the upper end of the guide vane arm cover 10 to the lower end, and is a portion into which the first measuring device 50 is inserted.

That is, the first measuring device 50 is installed on the upper end of the guide vane arm cover 10 , and the measuring needle of the first measuring device 50 is inserted into the insertion hole 11 , thereby being the shaft of the guide vane 30 . It will come into contact with the top.

Accordingly, the first measuring device 50 may measure the separation distance from the lower end of the guide vane arm cover 10 to the upper end of the shaft of the guide vane 30 .

On the other hand, the top cover 20 is provided with a second measuring mechanism (60).

The second measuring device 60 is provided at the right end of the top cover 20 , and is for measuring the separation distance between the lower end of the top cover 20 and the upper end of the blade of the guide vane 30 .

That is, the second measuring device 60 is installed at the right end of the top cover 20 , and the measuring needle of the second measuring device 60 comes into contact with the upper end of the blade of the guide vane 30 .

Accordingly, the second measuring device 60 may measure the separation distance from the lower end of the top cover 20 to the upper end of the blade of the guide vane 30 .

On the other hand, the bottom ring 40 is provided with a third measuring mechanism (70).

The third measuring device 70 is provided at the right end of the bottom ring 40 , and is for measuring the separation distance between the upper end of the bottom ring 40 and the lower end of the blade of the guide vane 30 .

That is, the third measuring device 70 is installed at the right end of the bottom ring 40 , and the measuring needle of the third measuring device 70 comes into contact with the lower end of the blade of the guide vane 30 .

Accordingly, the third measuring device 70 may measure the separation distance from the upper end of the bottom ring 40 to the lower end of the blade of the guide vane 30 .

On the other hand, the guide vane arm cover (10) is provided with an adjustment bolt (12).

The adjusting bolt 12 is provided at the upper end of the guide vane arm cover 10 , so that the guide vane 30 can be supported by the guide vane arm cover 10 , and the top cover 20 and the guide This is to adjust the separation distance between the vanes 30 and the separation distance between the bottom ring 40 and the guide vanes 30 .

That is, by tightening or loosening the adjusting bolt 12 , the distance between the lower end of the top cover 20 and the upper end of the blade of the guide vane 30 and the distance between the upper end of the bottom ring 40 and the lower end of the blade of the guide vane 30 . You can adjust the distance.

Of course, in the process of adjusting the adjustment bolt 12, the separation distance between the lower end of the guide vane arm cover 10 and the upper end of the shaft of the guide vane 30 is also adjusted.

The threaded portion of the adjustment bolt 12 is preferably formed to have a generous length in order to adjust the separation distance between the guide vane female cover 10 and the guide vane 30 .

On the other hand, the first measuring device 50 , the second measuring device 60 , and the third measuring device 70 are provided to be spaced apart from each other and connected to the first measuring device 50 and the second measuring device 60 by wire or wireless connection. ), a data management device 80 for processing and managing the measured values through the third measuring device 70 is provided.

The data management device 80 shows the measured values through the first measuring device 50 , the second measuring device 60 , and the third measuring device 70 , and the measured values may be accumulated and displayed. It could also be displayed in real time.

The data management device 80 may be configured to be fixedly installed in a specific place, or may be configured to be possessed by a specific person.

In addition, the first measuring device 50 , the second measuring device 60 , and the third measuring device 70 are detachably provided by magnetism.

That is, the first measuring device 50 , the second measuring device 60 , and the third measuring device 70 can be easily removed after measuring a gap in a specific region.

The first measuring device 50 , the second measuring device 60 , and the third measuring device 70 are best made in an electromagnet type.

The gap between the guide vane 30 and the top cover 20 and the bottom ring 40 can be precisely adjusted through the guide vane assembly auxiliary device of the water wheel according to the present invention configured as described above.

Hereinafter, a method for assembling a water wheel guide vane using the water wheel guide vane assembly dimension inspection device according to the present invention will be described.

The method for assembling the guide vane of the aberration according to the present invention includes a first measuring step (S10) of measuring the separation distance between the top cover 20 and the guide vane 30 with a second measuring device 60, and a third measuring device A second measurement step (S20) of measuring the separation distance between the bottom ring 40 and the guide vane 30 by 70, and the guide vane arm cover 10 and the guide vane 30 by the first measuring mechanism 50 ) A third measuring step (S30) of measuring the separation distance, and a reprocessing step (S40) of reprocessing the guide vane arm cover 10 using the measured value measured through the third measuring step (S30); It is configured to include an assembling step (S50) of assembling the reprocessed guide vane arm cover 10 through the reprocessing step (S40).

The first measuring step (S10) is to measure the separation distance between the lower end of the top cover 20 and the upper blade of the guide vane 30 through the second measuring mechanism (60).

Between the lower end of the top cover 20 and the upper end of the blade of the guide vane 30 by measuring the distance between the lower end of the top cover 20 and the upper end of the blade of the guide vane 30 through the first measuring step (S10) The separation distance may be adjusted to suit the designer's intention.

Here, adjusting to suit the designer's intention means setting the separation distance that can have the highest power generation efficiency according to environmental conditions in adjusting the separation distance between the lower end of the top cover 20 and the upper blade of the guide vane 30 means to do

The second measuring step (S20) is to measure the distance between the upper end of the bottom ring 40 and the lower end of the blade of the guide vane 30 through the third measuring mechanism 70.

Between the upper end of the bottom ring 40 and the lower end of the blade of the guide vane 30 by measuring the separation distance between the upper end of the bottom ring 40 and the lower end of the blade of the guide vane 30 through the second measuring step (S20) The separation distance may be adjusted to suit the designer's intention.

Here, adjusting to suit the designer's intention means setting the separation distance that can have the highest power generation efficiency according to environmental conditions in adjusting the separation distance between the upper end of the bottom ring 40 and the lower blade end of the guide vane 30 means to do

The third measuring step (S30) is to measure the separation distance between the lower end of the guide vane arm cover 10 and the upper end of the shaft of the guide vane 30 through the first measuring mechanism 50.

The third measuring step (S30) is preferably performed after the measured value obtained through the first measuring step (S10) and the measured value obtained through the second measuring step (S20) have mutually uniform values.

This is a high power generation efficiency when the distance between the lower end of the top cover 20 and the upper end of the guide vane 30 and the distance between the upper end of the bottom ring 40 and the lower end of the guide vane 30 have a mutually uniform value. because it has

That is, through the first measuring step (S10) and the second measuring step (S20), the separation distance between the lower end of the top cover 20 and the upper end of the guide vane 30 blade and the upper end of the bottom ring 40 and the guide vane 30 ) The third measuring step (S30) is performed after making the distance between the lower ends of the blades uniform.

The re-processing step (S40) is to re-process the guide vane arm cover 10 through the measured values obtained through the third measuring step (S30).

That is, the reprocessing step (S40) is performed by further processing the guide vane arm cover based on the measured value obtained through the third measuring step (S30). When the reprocessed guide vane arm cover 10 and the guide vane 30 are assembled The separation distance between the reprocessed guide vane arm cover and the guide vane 30 is to disappear.

Once again, the guide vane arm cover 10 is processed based on the measured value obtained through the third measuring step (S30), so that when combined with the guide vane 30, the guide vane arm cover 10 and the guide vane 30 ) is close.

The assembling step (S50) is to assemble the guide vane arm cover reprocessed through the reprocessing step (S40) to the guide vane 30 and the guide vane arm.

As described above, by the method of assembling the guide vane of the water wheel according to the present invention, the distance between the guide vane and the top cover and the bottom ring is adjusted almost uniformly while the distance between the guide vane female cover and the guide vane can be minimized.

That is, in the present invention, the separation distance between the guide vane, the bottom ring, and the top cover can be precisely adjusted, so that the leakage amount can be optimally controlled, thereby maximizing the efficiency of the aberration.

In addition, in the present invention, as the data management device is provided, measurement data is systematically managed, thereby minimizing time loss in adjusting the separation distance.

The scope of the present invention is not limited to the embodiments illustrated above, and within the technical scope as described above, many other modifications based on the present invention will be possible for those skilled in the art.

10. Guide vane arm cover 11. Insertion hole
12. Adjustment bolt 20. Top cover
30. Guide vane 40. Bottom ring
50. first measuring instrument 60. second measuring instrument
70. Third measuring instrument 80. Data management device
S10. First measurement step S20. second measurement step
S30. Third measuring step S40. reprocessing step
S50. assembly steps

Claims (5)

delete delete delete A first measuring step of measuring the separation distance between the top cover and the guide vane with a second measuring device;
a second measuring step of measuring the separation distance between the bottom ring and the guide vane with a third measuring device;
a third measuring step of measuring the separation distance between the guide vane arm cover and the guide vane with a first measuring device;
a re-processing step of re-processing the guide vane arm cover using the measured value measured through the third measuring step;
An assembly step of assembling the reprocessed guide vane female cover through the reprocessing step; 5. The method of claim 4,
and the third measuring step is performed after the measured value obtained through the first measuring step and the measured value obtained through the second measuring step have uniform values.

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