KR102065824B1 - A rectangular prism installing method on the large cavitation tunnel - Google Patents

Abstract

According to the present invention, in the experiment for observing propeller cavitation in a large cavitation tunnel, by installing a right angle prism in the observation window and filling water into the right angle prism, the cavitation of the propeller located on the left and right sides rather than the front of the observation window is performed. The present invention relates to a method of installing a right-angle prism device for observing propeller cavitation in a large cavitation tunnel, so that it can be clearly observed as if seen from the front without visible light refraction and distortion.

Description

A RECTANGULAR PRISM INSTALLING METHOD ON THE LARGE CAVITATION TUNNEL} for Observation of Propeller Cavitation in Large Cavitation Tunnels

The present invention relates to a method of installing a right angle prism device for observing propeller cavitation in a large cavitation tunnel, and more specifically, in an experiment for observing the propeller cavitation in a large cavitation tunnel, a right angle prism is installed in the observation window. By filling water inside the right angle prism, propellers in large cavitation tunnels can be clearly seen as if they are seen from the front without visible light refraction and distortion. A method of installing a right angle prism device for cavitation observation.

In general, the ship propeller is located at the rear of the ship, that is, the stern and is connected to the engine through the shaft system, and when the engine is operated, the propeller rotates by the rotational force of the shaft and generates the propulsion of the ship. It is a device that makes the ship move in the desired direction by turning or going straight.

In recent years, as the size and speed of ships are increased all over the world in order to increase the volume of cargo and secure the economics of ship operation, the engine horsepower is increased and the force required for propeller and rudder is rapidly increasing. Therefore, in the case of propellers and rudders, not only large ships but also ship types that have not been a problem in the past, the cavitation phenomenon is intensified, which causes serious engineering difficulties.

In particular, for various reasons, when the pressure on the surface of the object decreases and becomes below the vapor pressure (about 3 to 4 kPa at 150C), the surface of the object and water are separated and an empty space is created. This phenomenon is called cavitation. Cavitation phenomena occur in areas of low pressure on the surface of objects such as ship propellers, rudders, and rotating fluid machines, causing a lot of engineering difficulties.

More specifically, most cavitations have various types of cavitations, as shown below, depending on the size and distribution of the flow velocity (non-uniformity), pressure drop and pressure distribution around the object. This cavitation often occurs in combination because of the uneven flow rate distribution, or rotational operation, during wake.

The problems caused by cavitation in ships include 1) reduced thrust and propulsion efficiency, 2) increased hull surface fluctuations, 3) eroded wing surfaces, and 4) induced underwater noise.

Such cavitation can be classified into five types according to its type and characteristics, which are as follows.

First, sheet cavitation causes thrust reduction, hull surface fluctuation pressure and underwater noise when the amount of generation is large.

Next, bubble cavitation has a high breakdown force during collapse, which corrodes the wing surface and causes high pressure fluctuations and underwater noise.

Next, cloud cavitation occurs during the unstable collapse process as the thin film cavitation enters the high pressure region and causes high pressure fluctuations, surface erosion, and underwater noise.

Next, tip vortex cavitation occurs as the flow rolls up at the tip of the thruster wing and is extremely strong. In particular, due to the heterogeneous distribution, condensation bursts in the downstream of the propeller, and this increases the fluctuation pressure of higher order components, which causes a lot of difficulties in the actual design.

Finally, the hub vortex cavitation is a shape where the number of wings is twisted downstream from the propeller hub. The herb vortex cavities reach the rudders downstream, causing them to collapse, causing rudder surface erosion.

Therefore, in order to control the cavitation performance of the propeller and the rudder, as described above, the characteristics of the cavitation occurring in various forms must be accurately identified and analyzed for each type, and in particular, the characteristics of the cavitation vary according to the hull return distribution and size for each ship type. Therefore, it is necessary to develop a cavitation control technology in consideration of the three-dimensional flow characteristics of the hull.

In recent years, such a cavitation can be observed through a propeller rotation experiment in a large cavitation tunnel, for example, by artificially generating cavitation through a high speed flow in a state where a model ship, a propeller, and various additives are installed.

For example, the propeller of the model ship will be observed on the right at an angle of about 45 degrees from the center of one end of the large cavitation tunnel (eg, the sixth observation window). However, in the observation environment, an acrylic window of about 100 mm thickness and water of about 2.0 m depth exist between the propellers, so that the propellers are severely distorted while being refracted, and are visible to the viewer.

This distortion is caused by seven different scattered lights having different refractive indices when visible light is refracted. To solve this problem, it is necessary to reflect the visible light and look at the propeller installed at a 45 degree angle from the front. There is a need for a device that can achieve the same effect.

Therefore, in the experiment for observing the propeller cavitation in a large cavitation tunnel, the present inventors installed a right angle prism in the observation window and filled the water with the inside of the right angle prism, so that the propeller located on the left and right sides instead of the front of the observation window. A method of installing a right-angle prism device for observing propeller cavitation in a large cavitation tunnel has been invented so that cavitation can be clearly observed as if viewed from the front without visible light refraction and distortion.

Korean Patent Publication No. 10-2006-0133390

The present invention was derived to solve the above problems, in the experiment for observing the cavitation of the propeller in a large cavitation tunnel, by installing a right angle prism in the observation window, by filling the water inside the right angle prism, To provide a method of installing a right angle prism device for observing propeller cavitation in a large cavitation tunnel, which allows the cavitation of propellers located on the left and right sides instead of the front to be clearly seen as if viewed from the front without visible light refraction and distortion. do.

According to one or more exemplary embodiments, a method of installing a right angle prism device for propeller cavitation observation in a large cavitation tunnel may include fixing the first and second horizontal guide frames to the outside of an internal observation window provided in the cavitation tunnel. Prisms each of which protrudes at an angle of 45 degrees from the second vertical guide frame to be in contact with each other, and includes first and second external observation windows provided in the longitudinal direction on the first and second surfaces protruding outwardly, respectively. Fixing the frame to the first and second vertical guide frames, fixing the first and second vertical guide frames to the first and second horizontal guide frames, and the first and second horizontal guide frames and the A plurality of shots respectively provided between the prism frames and between the first and second vertical guide frames and the prism frames The elastic force adjusting bolts provided for each sieve are bolted to the bolt grooves provided in the first and second horizontal guide frames and the first and second vertical guide frames, respectively, and then rotated in one direction, respectively. It may include adjusting the elastic force.

According to an aspect of the present invention, by installing a right angle prism in the observation window and then filled with water inside the right angle prism, the cavitation of the propeller located on the left and right sides of the observation window, rather than the front of the observation window as if visible from the front without refraction and distortion As seen, it has the advantage of being able to observe clearly.

In particular, in the case of the acrylic observation window provided in the large cavitation tunnel, the surface may be contracted or expanded from -2.0mm to 6.0mm according to the pressure change. According to an aspect of the present invention, the prism frame is observed using the elastic force of the elastic body. By pushing to the inside of the prism frame in contact with the surface of the observation window to prevent leakage by using a silicone for preventing leakage, it has the advantage that can flexibly cope with the contraction and expansion of the acrylic observation window through the elastic body.

In addition, according to an aspect of the present invention, it is possible to adjust the elastic force of each elastic body, by adjusting the elastic force of the elastic body by only partially rotating the bolt only on the part of the leak, automatic displacement control of the elastic body even when the observation window is expanded Through this has the advantage of preventing the occurrence of gaps.

1 is a view showing the overall configuration in which a rectangular prism device 100 according to an embodiment of the present invention is installed in a large cavitation tunnel 1.
FIG. 2 illustrates the rectangular prism device 100 illustrated in FIG. 1 in more detail.
3 is a view showing the lower side of the rectangular prism device 100 shown in FIG.
4 is a view illustrating a state in which distortion occurs when cavitation of the propeller 2 is observed without passing through the rectangular prism device 100 according to an embodiment of the present invention.
FIG. 5 is a view illustrating a state where distortion does not occur when cavitation of the propeller 2 is observed through the rectangular prism device 100 shown in FIG. 2.
FIG. 6 is a view illustrating a process of observing the cavitation of the propeller 2 using the rectangular prism device 100 shown in FIG. 2 in order.

Hereinafter, preferred examples are provided to aid in understanding the present invention. However, the following examples are merely provided to more easily understand the present invention, and the contents of the present invention are not limited by the examples.

FIG. 1 is a view showing the overall configuration in which a right angle prism device 100 according to an embodiment of the present invention is installed in a large cavitation tunnel 1, and FIG. 2 shows a right angle prism device 100 shown in FIG. Specifically, FIG. 3 is a view showing the lower side of the rectangular prism device 100 shown in FIG. 2.

1 to 3, the large cavitation tunnel 1 is provided with seven or more internal observation windows 3 in the direction of water flow, wherein the interior of the large cavitation tunnel 1 through each internal observation window 3. Will be observed.

In particular, it can be seen that the right angle prism device 100 according to the embodiment of the present invention is installed in the sixth internal view window from the left side of the figure, and is located in the seventh internal view window from the left side through the right angle prism device 100. Cavitation of the propeller 2 can be observed in front. In addition, the inside located in the fifth internal viewing window from the left side through the right angle prism device 100 can also be observed in front. The perpendicular prism 100 device for enabling the frontal injection will be described in more detail.

The orthogonal prism device 100 according to the embodiment of the present invention is largely divided into the first and second horizontal guide frames 110 and 120, the first and second vertical guide frames 130 and 140, and the prism frame 150. And first and second external observation windows 151a and 152a.

First, the first and second horizontal guide frame (110, 120) is bolted to one or more fixing groove (1a) provided on the outside of each inner observation window (3) of the large cavitation tunnel 1, thereby, the large cavitation tunnel The height in the vertical direction can be adjusted from the internal observation window 3 in (1).

To this end, fixing bolts 111 and 121 which are bolted to the one or more fixing grooves 1a may be provided at both end portions of each of the first and second horizontal guide frames 110 and 120, and fixing bolts 111, The first and second horizontal guide frames 110 and 120 can be separated from the fixing groove 1a by releasing 121, and the heights of the separated first and second horizontal guide frames 110 and 120 are adjusted. After that, it can be fixed again.

As shown in FIG. 2, the first and second horizontal guide frames 110 and 120 serve as a kind of horizontal support, and the shape thereof is not limited.

Next, the first and second vertical guide frames 130 and 140 may be bolted in the vertical direction of the first and second guide frames 110 and 120 described above, and likewise the first and second vertical guide frames The fixing bolts 131 and 141 which are bolted to one or more fixing grooves 110a and 120a provided in the first and second horizontal guide frames 110 and 120 may be provided at both ends of each of the ends 130 and 140. have.

Therefore, as the fixing bolts 131 and 141 provided at both ends of each of the first and second vertical guide frames 130 and 140 are bolted to the one or more fixing grooves 110a and 120a, the first and second fixing guide bolts 130 and 140 are bolted to each other. Left and right positions of the first and second vertical guide frames 130 and 140 may be adjusted on the horizontal guide frames 110 and 120. Meanwhile, the first and second vertical guide frames 130 and 140 support the prism frame 150 so that the prism frame 150, which will be described later, may be brought into close contact with the internal observation window 3 of the large cavitation tunnel 1. Note that the type of support that can serve as a support is not limited.

Next, the prism frame 150 protrudes outward from the first and second vertical guide frames 130 and 140 at an angle of 45 degrees, respectively, so that the ends thereof are in contact with each other, and the inner prism frame 3 is formed. The separation space is formed, and the space is filled with water as the space is filled to play a role as a prism.

More specifically, the prism frame 150 is provided with first and second external observation windows 151a and 152a on the first and second surfaces 151 and 152 protruding outwardly, wherein the first and second external observation windows 151a and 152a are provided. The external observation windows 151a and 152a may be made of acrylic material, which is the same material as the internal observation window 3, respectively. Therefore, as the refractive indexes of the filled water and the inner viewing window 3 and the first and second outer viewing windows 151a and 152a are all maintained correspondingly, a small distortion of the joint surface where the filled water is in contact with the water interference As a result, the distortion is overcome.

In particular, when water is filled in the space spaced from the inner viewing window 3, the visible light for the inner region in the large cavitation tunnel 1 adjacent to the inner viewing window 3 is transmitted to the first and second outer viewing windows. As it is incident and reflected at a 45 degree angle through any one of 151a and 152a, the internal viewing window 3 (more specifically, as shown in FIG. 1) through the first and second external viewing windows 151a and 152a. An inner region adjacent to the sixth inner viewing window (for example, an area in the fifth inner viewing window or an area in the seventh inner viewing window of FIG. 1) is emitted to the viewer in front.

On the other hand, when the internal observation window 3 of the large cavitation tunnel 1 is made of glass, the first and second external observation windows 151a and 152a may be similarly applied to the glass material. Note that the materials of the observation windows 151a and 152a are not limited.

In one embodiment, the first and second horizontal guide frame 110, 120 and the prism frame 150, and between the first and second vertical guide frame 130, 140 and the prism frame 150, respectively Two elastic bodies 160 may be provided.

Referring to FIG. 2, the plurality of elastic bodies 160 are formed on an outer side of a plate made of SUS material provided on the lowermost side of the prism frame 150 (the closest portion to the internal observation window 3 on FIG. 1), and the first and the first materials. It can be seen that a plurality of horizontal guide frames 110 and 120 and between the first and second vertical guide frames 130 and 140 are provided.

Accordingly, the plurality of elastic bodies 160 push the plate of the SUS material as described above, and as a result, the prism frame 150 may be in close contact with the inner viewing window 3. This is to flexibly cope with the elastic force of the plurality of elastic bodies 160 when the internal observation window 3 is expanded or contracted due to the internal hydraulic pressure of the large cavitation tunnel 1, The elastic force of the 160 allows the adhesion between the prism frame 150 and the internal viewing window 3 to be kept constant at all times. That is, even when the inside observation window 3 is expanded, gaps are not generated due to automatic displacement adjustment of each of the plurality of elastic bodies 160, so that the water filled therein does not leak to the outside.

In particular, one side of the plurality of elastic body 160 is provided with an elastic force adjusting bolt 160a for adjusting the elastic force of each elastic body, each of the elastic force adjusting bolts are the first and second horizontal guide frame (110, 120), As the bolt is coupled to the bolt groove provided in each of the first and second vertical guide frames 130 and 140 and rotates in one direction, an elastic force for each of the plurality of elastic bodies 160 may be adjusted.

By individually adjusting the elastic force of the plurality of elastic bodies 160, by further pushing the bolt of the portion in which the leak occurs, it is possible to increase the compressive force of the elastic body 160 of the corresponding portion to cope with the occurrence of gaps.

On the other hand, as the first and second external observation windows 151a and 152a meet at right angles to each other, the observer opens the sixth internal observation window of the large cavitation tunnel 1 through the first external observation window 151a. When viewed, the inner region of the seventh inner viewing window of the large cavitation tunnel 1 is ejected to the front through the first outer viewing window 151a.

In addition, when the observation vehicle views the sixth internal observation window of the large cavitation tunnel 1 through the second external observation window 152a, the inner region of the fifth internal observation window of the large cavitation tunnel 1 is the second external observation window. It is injected to the front through 152a.

In an embodiment, the water that is filled in the space between the prism frame 150 and the internal viewing window 3 is in close contact with the prism frame 150 and leaks from the gap between the prism frame 150. A leakage preventing plate 153 may be provided to prevent the leakage. The leakage preventing plate 153 may be formed of a silicon material, and fills a minute gap that may be generated in the close contact space between the internal observation window 3 and the prism frame 150.

Also, in one embodiment, one side of the prism frame 150 may be provided with a water injection unit 154 for filling the water, the water injection unit 154 is located on the upper side of the prism frame 150, for example Or on the lower side.

Next, the state which observes the propeller 2 without actually using the rectangular prism apparatus 100 via FIG. 4 and FIG. 5, and the state which observes the propeller 2 using the rectangular prism apparatus 100 is shown. Let's look at it.

4 is a view illustrating a state in which distortion occurs when cavitation of the propeller 2 is observed without passing through the rectangular prism device 100 according to an embodiment of the present invention, and FIG. 5 is shown in FIG. When the cavitation of the propeller 2 is observed through the right angle prism device 100, it is a diagram illustrating a state in which no distortion occurs.

First, referring to FIG. 4, FIG. 2 shows a state in which the propeller 2 is obliquely observed at an angle of 45 degrees through the sixth internal observation window of the large cavitation tunnel 1, between the observation position and the propeller 2. It can be seen that cavitation of the propeller 2 is severely distorted and ejected while refraction of visible light occurs due to the interval, the thickness of the internal observation window, and the water depth.

This is because, when the propeller 2 is located between the sixth internal observation window and the seventh internal observation window, distortion may occur at any angle, making it difficult to observe the sharp cavitation of the propeller 2. It may mean.

Referring to FIG. 5, the right angle prism device 100 is installed in the sixth inner viewing window of the large cavitation tunnel 1 under the same conditions as in FIG. 3, and the propeller 2 is mounted through the first outer viewing window 151a. It will show the state observed obliquely at an angle. At this time, the refraction may occur due to the distance between the observation position and the propeller 2, the thickness of the internal observation window, the depth of the water, etc. Since it is ejected to the front through the first external observation window 151a, it can be seen that the cavitation of the propeller 2 is clearly ejected without distortion.

That is, through the right angle prism device 100, even if the propeller 2 is located between the 6th internal view window and the 7th internal view window, it is possible to observe the clear cavitation of the propeller 2 without distortion, regardless of the angle. do.

Next, a series of processes for observing the cavitation of the propeller 2 using the right angle prism device 100 will be described in order with reference to FIG. 6.

FIG. 6 is a view sequentially illustrating a process of observing the cavitation of the propeller 2 using the rectangular prism device 100 shown in FIG. 2.

Referring to FIG. 6, first, fixing bolts 111 and 121 are disposed in one or more fixing grooves 1a while positioning the first and second horizontal guide frames 110 and 120 on the outside of the internal observation window provided in the large cavitation tunnel 1. Fix by bolting (S601).

Next, the first and second vertical guide frames 130 and 140 are positioned in the vertical direction on the first and second horizontal guide frames 110 and 120, respectively. Fixing bolts (131, 141) provided at both ends of each side is fixed by bolting to one or more fixing grooves (110a, 120a) (S602).

Next, the prism frame 150 is fixed to the first and second vertical guide frames 130 and 140 (S603), and the elastic force adjusting bolt 160a provided on one side of the plurality of elastic bodies 160 in one direction. By rotating the prism frame 150 is in close contact with the internal observation window (S604).

Next, water is filled in the space formed between the inner observation window 3 and the prism frame 150 so that the first and second outer observation windows 151a and 152a serve as right angle prisms (S605). .

Then, when the observer stares directly at the first and second external observation windows 151a, 152a, the inner region adjacent to the internal observation window 3 through the first and second external observation windows 151a, 152a. The viewer is ejected to the front (S606).

While the foregoing has been described with reference to preferred embodiments of the invention, those skilled in the art will be able to variously modify and change the invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

1: large cavitation tunnel
1a: fixing groove
2: propeller
3: internal view window
100: right angle frame device
110: first horizontal guide frame
110a: fixing groove
111: fixing bolt
120: second horizontal guide frame
120a: fixing groove
121: fixing bolt
130: first vertical guide frame
131: fixing bolt
140: second vertical guide frame
141: fixing bolt
150: prism frame
151: first page
151a: first external observation window
152: second side
152a: second external observation window
153: leakproof plate
154: water inlet
160: elastomer
160a: elasticity adjustment bolt

Claims (6)

Fixing the first and second horizontal guide frames to the outside of the internal viewing window provided in the cavitation tunnel;
Ends protrude from the first and second vertical guide frames at an angle of 45 degrees, respectively, and are formed in contact with each other. And first and second external observation windows having refractive indices corresponding to the internal observation windows, and a water injection part into which water is injected is provided on an upper surface of the first and second prism frames, which serve as a prism by the filled water. Securing to the vertical guide frame;
Fixing the first and second vertical guide frames to the first and second horizontal guide frames; And
The prism frame is guided to the first and second horizontal guides through a plurality of elastic bodies provided between the first and second horizontal guide frames and the prism frame, and between the first and second vertical guide frames and the prism frame, respectively. As the frame is pushed from the first and second vertical guide frames toward the inner viewing window, the adhesion between the prism frame and the inner viewing window increases, and the elastic force adjusting bolts provided for the plurality of elastic bodies are respectively provided in the first view. And a bolt coupled to a bolt groove provided in each of the second horizontal guide frame and the first and second vertical guide frames, and then rotated in one direction so that water leaks from a close contact surface between the prism frame and the inner viewing window of a plurality of elastic bodies. Where the elastic force of the elastic body located in the part where the Including;
When water is filled in the space between the inner viewing window and the prism frame, visible light for an inner region of the cavitation tunnel adjacent to the inner viewing window is incident at a 45 degree angle through one of the first and second outer viewing windows. And as reflected, an inner region adjacent to the inner viewing window is ejected to the viewer through the first and second outer viewing windows.
Both end portions of each of the first and second horizontal guide frames are provided with fixing bolts that can be bolted to at least one fixing groove provided on the outside of the inner viewing window, and through the bolt coupling of the fixing bolts. The height of the first and second horizontal guide frame relative to,
Both ends of each of the first and second vertical guide frames are provided with fixing bolts that can be bolted to at least one fixing groove provided on the first and second horizontal guide frames, and through the bolt coupling of the fixing bolts. Left and right positions of the first and second vertical guide frames with respect to the horizontal direction of the inner viewing window is adjusted,
The close contact surface between the prism frame and the inner viewing window prevents water filled in the space spaced from the inner viewing window from leaking to the outside of the prism frame, and is generated in a close contact space between the inner viewing window and the prism frame. A method of installing a right-angle prism device for observing propeller cavitation in a large cavitation tunnel, wherein a leak-proof plate of silicon is provided to fill the gap. delete delete delete delete delete

Images