KR101508984B1 - Large Cavitation Tunnel equiped with module type observation part - Google Patents

Abstract

The present invention provides a large cavitation tunnel having a module type observation unit which includes: an upper section (100) having a tunnel observation unit (130) to perform a cavitation experiment of a propeller, and an aileron installed in a model ship and a first bent part (320) and a fourth bent part (310) on both sides; and a lower section (200) connected to the upper section (100) flowing water filled inside the lower section which is full of water to be induced to the tunnel observation unit (130) at a predetermined flow rate through an impeller shaft device equipped inside the lower section having a second bent part (330) and a third bent part (340) on both sides. The tunnel observation unit (130) includes: a duct of the observation unit (131) having the opened upper portion; and a trunk (132) attached and detached to the upper portion of the duct of the observation unit (131) by a hanging method, and inserting the lower portion of the model ship into the duct of the observation unit (131) to be fixated. The duct of the observation unit (130) has a plurality of observation windows (131a) on the upper portion of both side surfaces.

Description

[0001] The present invention relates to a large cavitation tunnel equipped with a modular observation unit,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circulating large-size cavitation tunnel, and more particularly to a large-sized cavitation tunnel having a modular observation section.

Generally, the observation part provided in a large-sized cavitation tunnel is a test space for testing the force, pressure, velocity measurement, and underwater noise measurement by the cavitation test of the model line or the impregnated body and fluid flow, The observation windows should be arranged so that the model lines attached to the upper surface of the secondary duct and the flow characteristics of the stern section and surroundings of the moor body installed at the center are well observed and measured.

In the observation duct, the upper and lower surfaces are completely opened, connected to the trunk and the acoustic trough, respectively, and both sides are provided with a number of observation windows. And deformation should be valid.

However, the position of the observation window is inevitably placed at the midpoint of the side of the observation duct in order to withstand the required structural strength according to the flow velocity and flow pressure of the water flowing into the observation duct, the difference in static pressure inside and outside the observation structure, As the size of the observation window became smaller, there was an inconvenience that observation and measurement were not performed properly during the cavitation test of the model line or the impregnated body.

Accordingly, it is an object of the present invention to provide a large-sized cavitation tunnel including a modular observation unit having observation windows on both sides of observation side ducts through observation side ducts having a modular structure to solve the above-mentioned problems.

Korean Patent Registration No. 10-1259260 (entitled "Installation Device for Experiments in a Large Cavitation Tunnel of a Wide Model Line)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a large-sized cavitation tunnel including a modular observation unit having observation windows on both sides of observation sub- will be.

Another problem to be solved by the present invention is to suppress the flow noise generated due to the flow of water circulated in the circulation type large cavitation tunnel, thereby enabling the flow noise measurement at the model line to be possible. In the case of the circulation type large cavitation tunnel And a large cavitation tunnel having a modular observation part that can solve the problem that cavitation experiment of the model propeller and the rudder can not be smoothly performed when uneven flow generated in the rotation section flows into the observation side duct.

In order to solve the above-described problems, a large-sized cavitation tunnel having a modular tunnel observation unit according to an embodiment of the present invention includes a tunnel observation unit 130 for measuring cavitation experiments of a propeller and a rudder mounted on a model line, An upper section 100 having a first bend section 320 and a fourth bend section 310; And the upper section 100 and flows through the impeller shaft device installed therein to flow the water filled in the tunnel into the tunnel observing section 130 at a predetermined flow rate and the second bend section 330 And a lower section 200 having a third bent section 340. The tunnel observation section 130 includes an observation section duct 131 having an upper portion opened; And a trunk (132) detachably attached to the upper portion of the observation duct (131) in a hooking manner and drawing a lower portion of the model line into the observation duct (131) Is characterized in that a plurality of observation windows (131a) are disposed on the upper side of both sides to ensure easiness of the cavitation test observation of the model lines.

The trunk 132 is provided with a draft plate 132a fastened to the lower portion to suppress waves generated due to the water flowing in the observation duct 131. The draft plate 132a has a lower portion And a model wire entry port 132b which is drawn in and closely contacted with the inside is provided.

The trunk 132 is provided with a connecting member connected to the model line restraining device 135 which moves the model line in a height direction to fix the position thereof.

And a trunk upper cover 136 detachably attached to the upper portion of the trunk 132. [

The observation duct (131) is provided with an acoustic trough (131c) provided with an acoustic measurement device mounted with an acoustic sensor at a lower portion thereof.

The observation side duct 131 further includes an acoustic window 131b on the bottom surface thereof and the acoustic window 131b is connected to the observation side duct 131 through the acoustic trough 131c. And the acoustic toup 131c includes a carrier for performing a planar movement of the acoustic measurement equipment; And a sound absorbing material for preventing reflection of noise transmitted to the acoustic window 131b.

The model line restraining device 135 is characterized in that a height adjusting member 135a for adjusting the height is provided.

The large cavitation tunnel having the modular observation part according to the embodiment of the present invention can be provided with observation windows on both sides of the observation side duct to more easily observe and measure the flow field at the stern and bottom end of the model line, Can be performed more precisely and conveniently.

In addition, by making the observation duct in the tunnel observation part modular, it is possible to facilitate the connection with the observation window, as well as the deformation of the structure due to dynamic pressure due to the flow introduced into the observation side duct, pressure change in the tunnel, It has an advantage that it can overcome the limit of the observation window arrangement due to the intensity.

Further, in the first bent portion to the cavitation tunnel by suppressing the generation exfoliation of the flow in the respective bent portion by four bend the first bending portion to Claim 4 90 ^o rotation facilitates the water flow direction through the bent portion through the vanes provided on each The generated flow noise can be minimized.

In addition, it is possible to uniformize the flow circulated through the rectifying section provided with the two-stage honeycomb at the front end of the tunnel observation section and to reduce the turbulence intensity, so that the cavitation test of the model line and the force, Measurement, underwater noise measurement, and the like can be uniformly performed.

1 is a view illustrating a structure of a large-sized cavitation tunnel having a modular observation unit according to an embodiment of the present invention.
2A is an assembly flow chart of the tunnel observation unit shown in FIG.
FIG. 2B is a vertical cross-sectional view of the tunnel observation unit shown in FIG. 1. FIG.
3 is a side view of the observation duct shown in FIG.
4 is a top view of the observation duct shown in Fig.
5 is a perspective view showing a first honeycomb unit and a second honeycomb unit provided in the rectifying unit shown in FIG.
6 is an enlarged view of A in Fig.
7 is an enlarged view of B in Fig.
8A is an enlarged view of the first to fourth bends.
8B is an enlarged view of a guide vane disposed in each bend.
FIG. 9 is an exemplary view showing the impeller shaker apparatus according to the present invention.
FIG. 10 is a view showing a state in which a shaft bearing bracket provided in a shaft duct 210 of the present invention is coupled to a shaft bearing.
11A is an exemplary view showing a stator 231 provided in the stator duct 230 shown in FIG.
11B is an actual view of the stator 231. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Embodiments in accordance with the concepts of the present invention can make various changes and have various forms, so that specific embodiments are illustrated in the drawings and described in detail in this specification or application. It is to be understood, however, that it is not intended to limit the embodiments according to the concepts of the present invention to the particular forms of disclosure, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between. Other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises" or "having & But are not intended to specify the presence of stated features, integers, steps, operations, components, parts, or combinations thereof, unless the presence or absence of one or more other features, Or < / RTI >

Hereinafter, a low noise large cavitation tunnel according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a view illustrating a structure of a large-sized cavitation tunnel having a modular observation unit according to an embodiment of the present invention.

2A is an assembly flow chart of the tunnel observation unit shown in FIG.

FIG. 2B is a vertical cross-sectional view of the tunnel observation unit shown in FIG. 1. FIG.

3 is a side view of the observation duct shown in FIG.

4 is a top view of the observation duct shown in Fig.

5 is a perspective view showing a first honeycomb unit and a second honeycomb unit provided in the rectifying unit shown in FIG.

6 is an enlarged view of A in Fig.

7 is an enlarged view of B in Fig.

8A is an enlarged view of the first to fourth bends.

8B is an enlarged view of a guide vane disposed in each bend.

FIG. 9 is an exemplary view showing the impeller shaker apparatus according to the present invention.

FIG. 10 is a view showing a state in which a shaft bearing bracket provided in a shaft duct 210 of the present invention is coupled to a shaft bearing.

11A is an exemplary view showing a stator 231 provided in the stator duct 230 shown in FIG.

11B is an actual view of the stator 231. Fig.

As shown in FIG. 1, a large cavitation tunnel 1000 having a modular observation part of the present invention includes an upper section 100 and a lower section 200.

The upper section 100 is provided with a tunnel observing section 130 for measuring the cavitation experiment of model lines and has a fourth bend section 310 and a first bend section 320 on both sides.

The lower section 200 is connected to the upper section 100 and flows through the impeller shaft device 500 provided therein to flow water filled therein to flow into the tunnel observation section at a predetermined flow rate, The second bend section 330 and the third bend section 340 are provided.

Here, the first bent portion 320 to the fourth bent portion 310 are formed in a curved shape, and guide vanes 400 for suppressing flow noise of water are arranged in a predetermined direction, (Not shown) is filled in the inside of the vane 400 to suppress the vibration of the vane itself and the noise generated due to the vibration, and a detailed description will be given later.

More specifically, the upper section 100 uniformizes the flow of the first bending section 151 through the first and second honeycomb sections 111 and 112 and reduces the turbulence intensity, The first honeycomb unit 111 and the second honeycomb unit 112 are formed to be detachable from the rectifying unit 110 while being separated from each other through a guide member .

The first honeycomb unit 111 and the second honeycomb unit 112 have a honeycomb structure in which a plurality of honeycomb blocks are arranged in a grid pattern and the honeycomb block has a honeycomb structure in which a plurality of honeycomb holes 111a and 112a are arranged at regular intervals, And the cross sections of the honeycomb holes 111a and 112a are formed in a hexagonal shape.

The diameter of the honeycomb hole 111a in the first honeycomb unit 111 is designed to be larger than the diameter of the honeycomb hole 112a in the second honeycomb unit 112. [

The upper section 100 further includes a contraction section 120 between the rectification section 110 and the tunnel observation section 130. The contraction section 120 is a part of the flow of water passing through the rectification section 110, And shrinks the flow of the water to lower the turbulence intensity.

The contraction portion 120 has an area ratio of an inlet 121 connected to the rectifying portion 110 and an outlet 122 connected to the tunnel inspecting portion 130 of 5.2: 1, And the lower surface may be in the form of a grub.

The upper section 100 is provided between the tunnel observation section 130 and the first bend section 320 and includes a main diffusion section 140 for alleviating the flow rate of water flowing out from the tunnel observation section 130 ).

Hereinafter, the tunnel observing unit 130 will be described in more detail with reference to the drawings.

The tunnel observation side duct (131) is a test space for performing at least one of a force test, a pressure test, a velocity test, and an underwater noise test by a cavitation test and a fluid flow of a model line or an impregnated body, A rectangular cross section having a width of 2.8 m, a depth of 1.8 m and a length of 12.5 m and having a constant square cross-sectional area immediately after the contraction portion 120 and having a corner corner fillet (not shown) exist.

More specifically, the tunnel observing unit 130 includes an observing duct 131 and a trunk 132.

The observation sub-duct 131 is formed in a rectangular parallelepiped structure having an open top, and a plurality of observation windows 131a may be disposed on both sides of the observation sub-duct 131. More preferably, 14 observation sub- An observation window is established.

The observation window, the observation window is associated with the frame (Viewing Window) (131a) is to be easily detachable with the observation window (131a), and must also be designed to ensure the safety lock and water-tight under operating pressure and speed. In addition, in order to reduce noise due to flow and peeling, a planar agreement between the inner surface of the observation portion duct 131 and the inner surface of the observation window 131a is important.

In addition, the position of the observation window 131a is formed so as to have a rectangular shape at a position which is maximally raised to the upper side of the observation duct to ensure easiness of the test observation.

The observation window 131a is made of a special plastic material (polymethyl methacrylate plastic) finely processed optically and the structural stability of the observation window 131a must be secured to withstand the pressure of the observation side duct 131.

Acoustic troughs 131c are provided below the observation ducts 131 and an acoustic window 131b is provided between the observation ducts 131 and the acoustic troughs 131c. Respectively.

The trunk 132 is detachably attached to the upper portion of the observation duct 131 in a hook manner and functions to draw the lower portion of the model line into the observation duct 131 and fix it.

More specifically, the trunk 132 is provided with a water level plate 132a, which is connected to the lower part of the observation channel duct 131 in order to prevent water flowing into the inside of the observation channel duct 131 from flowing into the water level and generating waves, Is provided with a model line inlet port 132b in which a lower portion of the model line is drawn in and brought into close contact therewith.

In addition, the trunk 132 is provided with a connecting member (not shown) connected to the model line restraining device 135 for fixing the position by moving the model line in the height direction on the upper inner side surface.

The trunk 132 may further include a trunk upper cover 136 detachable from the upper portion.

The observation side duct 131 further includes an acoustic window on the bottom surface thereof and the acoustic window is provided to allow the water in the observation side duct 131 to be introduced into the acoustic trough 131c .

The observation duct 131c may be provided with at least one observation window 131a at the upper end of the outer side surface thereof and an acoustic trough provided with an acoustic measurement device having an acoustic sensor mounted thereunder.

Here, the acoustic trough 131c may include a carrier (not shown) for performing a plane movement of the acoustic measurement device and a sound absorbing material (not shown) for preventing reflection transmitted through the acoustic window 131b have.

The main diffusion portion 140 may be formed in a rectangular cross-sectional shape in which a corner corner fillet is provided at each corner. A portion of the main diffusion portion 140 up to the first 3 m from the start of the main diffusion portion 140 is referred to as a Transition This part functions to alleviate a sudden change in flow from the tunnel observing unit 130 to the main diffusion unit 140.

The lower section 200 includes a duct section 250 for supporting the impeller shaft device and the duct section 250 includes a shaft duct 210, an impeller duct 220 and a stator duct 230 .

The shaft duct 210 may be a cylindrical duct having a shaft bearing bracket 211 for supporting an impeller driving shaft of the impeller shaft device.

The impeller duct 220 may be a cylindrical duct surrounding the impeller of the impeller shaker.

The stator duct 230 may be a cylindrical duct for supporting the stator of the impeller shaft device, and the stator 231 may include the diffuser vane 232.

The lower section 200 further includes a cylindrical lower diffusion section 260 for stabilizing the downstream flow velocity of the impeller.

A transition duct 270 having a structure in which a cross section is changed from a cylindrical shape to a quadrangular shape is provided between the lower diffusion portion 260 and the third bend portion 340. The transition duct 270 includes a lower diffusion portion 260 May be a space that transitions from a cylindrical cross-sectional flow to a rectangular cross-sectional flow.

Hereinafter, the first to fourth bends 320 to 310 will be described in more detail.

A plurality of guide vanes (V) are provided in the first to fourth bends (320) to (310) so as to smooth the flow of the flow.

The guide vane (V) performs a function of minimizing the flow noise in the tunnel by reducing the variation of the dynamic pressure so that the flow introduced into each bent portion is smoothly rotated by 90 ^° so that the flow separation does not occur.

In order to minimize the flow noise, a damping material is provided inside the cross section of the guide vane in order to prevent vibration of the vane itself and noise caused thereby.

Meanwhile, a splitter (S) for preventing deflection of the guide vane is provided in the middle of the guide vanes provided in each bent portion, thereby maintaining the shape of the vane constant.

Therefore, in the large-sized cavitation tunnel having the modular observation unit according to the embodiment of the present invention, observation windows can be provided on both sides of the observation side duct, so that the stern and the lower end of the model line can be observed more easily, And can be performed precisely.

In addition, by making the observation duct in the tunnel observation part modular, it is possible to easily combine with the observation window and to overcome the limitation of the observation window arrangement due to the dynamic pressure and the internal pressure change due to the flow introduced into the observation side duct .

Also, the first bent portion 320 to the fourth bent portion 310 a through the vane the first bent portion 320 to the fourth bent portion to smoothly rotated 90 ^o the direction of flow of water passing through the unit 310, each bent portion is provided on each It is possible to minimize the flow noise generated in the cavitation tunnel by suppressing the occurrence of the flow separation phenomenon in the cavitation tunnel.

In addition, the flow circulating through the rectifying part provided with the two-stage honeycomb unit at the front end of the tunnel observation part can be made uniform and the turbulence intensity can be reduced, so that the cavitation test of the model line and the force, Measurement, underwater noise measurement, and the like can be uniformly performed

The previous description of the disclosed exemplary embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these exemplary embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention.

1000: Large cavitation tunnel with modular observation
100: upper section 110: rectifying section
111: first honeycomb unit 112: second honeycomb unit
111a, 112a: Honeycomb hole 120: Shrinkage part
130: Tunnel observation part 131: Observation part duct
131a: observation window 131b: acoustic window
131c: acoustic trough 132: trunk
132a: draft plate 132b: model line inlet
135: Model line restraining device 135a: Height adjusting member
136: trunk upper cover 140: main diffusion portion
200: Lower section 250: Duct section
210: shaft duct 220: impeller duct
230: stator duct 260: lower diffusion part
270: transition duct 310: fourth bend \
320: first bend
330: second bend 340: third bend
610: first pillar part 620: second pillar part
V: Guide vane B: Honeycomb block

Claims (8)

An upper section 100 provided with a tunnel observing section 130 for measuring a cavitation experiment of a model line and having a fourth bend section 310 and a first bend section 320 on both sides; And
The second bend section 330 is connected to the upper section 100 and flows through the impeller shaft device installed therein to allow the water to flow into the tunnel observation section 130 at a predetermined flow rate. And a lower section 200 having a third bend section 340,
The tunnel observing unit (130)
An observation duct (131) having an open top; And
And a trunk (132) detachably attached to the upper part of the observation part duct (131) in a hanging manner and drawing the lower part of the model line into the observation part duct (131)
The observation sub-duct (130)
A plurality of observation windows 131a are disposed on the upper and lower sides of the model lines to ensure easiness of the cavitation test observation of the model lines,
The observation window (131a)
Wherein the tunnel is formed of an optically processed polymethyl methacrylate plastic. 2. The large-capacity cavitation tunnel according to claim 1,
The method according to claim 1,
The trunk (132)
The bottom plate 132a is provided with a lower portion of the model line which is inserted into the inside of the observation portion duct 131 to be in close contact with the lower portion of the observation plate 131, And a model line inlet port (132b) is provided on the outer surface of the large-sized cavitation tunnel.
3. The method of claim 2,
The trunk (132)
And a connecting member connected to the model line restraining device 135 for moving the model line in a height direction and fixing the position of the model line to the upper inner side surface of the large cavitation tunnel.
The method of claim 3,
Further comprising a trunk upper cover (136) detachably attached to an upper portion of the trunk (132).
5. The method of claim 4,
The observation sub-duct (131)
And an acoustic trough (131c) provided with an acoustic measurement device equipped with an acoustic sensor at a lower portion thereof is provided in the large cavitation tunnel.
6. The method of claim 5,
The observation sub-duct (131)
The acoustic window 131c further includes an acoustic window 131c on the bottom surface to prevent water from entering the observation duct 131 into the acoustic trough 131c Function,
The acoustic toup 131c is a sound-
A carrier for performing a planar movement of the acoustic measurement device; And
And a sound absorbing material for preventing reflection to be transmitted to the acoustic window (131c) is included in the large cavitation tunnel.
delete The method of claim 3,
The model line restraining device (135)
And a height adjustment member (135a) for adjusting the height of the tunnel.

Images