KR102212475B1 - Transverse velocity calibration apparatus for 3d ldv system - Google Patents

Abstract

The present invention relates to a transverse flow velocity correction device of a 3D LDV device for verifying and correcting a transverse flow velocity of fluid around a propeller and a model ship inside a large cavitation tunnel measured through a 3D LDV device, which compares the transverse flow velocity expected according to an injection angle change of water injected to an adjacent position to focuses of different laser beams with the transverse flow velocity measured through the actual 3D LDV device to verify the accurate transverse flow velocity.

Description

Transverse flow velocity correction device of 3D LDV device {TRANSVERSE VELOCITY CALIBRATION APPARATUS FOR 3D LDV SYSTEM}

The present invention relates to a transverse flow velocity correction apparatus of a 3D LDV apparatus, and more specifically, in verifying and correcting the transverse flow velocity of a fluid around a model ship and a propeller in a large cavitation tunnel measured by a 3D LDV apparatus. , It is possible to verify an accurate lateral flow rate by comparing the expected lateral flow rate according to the change of the spray angle of water sprayed at the focal point of different laser beams and adjacent locations, and the lateral flow rate measured by the actual 3D LDV device. It relates to a transverse flow velocity correction device for a three-dimensional LDV device that enables it.

In general, LDV (Laser Doppler Velocimetry) is a device that measures the flow velocity around model ships and propellers by using a laser beam (BEAM), and it is known that separate correction is not required if the alignment of the laser beams is well done. .

On the other hand, in order to measure the flow velocity in one direction, the focus of two laser beams must be focused.In the case of a large cavitation tunnel, a 100t-thick acrylic window may have a thickness difference of 2mm or more depending on its location, so the incident angle of the laser beam, etc. It was required to verify the axial and transverse flow velocities obtained only with the information of.

Conventionally, a rotating disk was mainly used to verify the axial flow velocity of the fluid measured through the LDV equipment. When the rotating disk is connected to the motor, the focal point of the LDV laser beam is placed on the disk surface and the rotation speed of the motor is adjusted to determine the disk surface speed. Therefore, the speed can be corrected by comparing the speed measured by the LDV equipment.

However, in the case of a laser beam irradiated in the transverse direction of a large cavitation tunnel, since transverse flow velocity verification is not possible with a rotating disk, a separate verification device capable of verifying the transverse flow velocity is currently required.

Korean Patent Registration No. 10-1556251

The present invention was derived to solve the above-described problem, and in verifying and correcting the lateral flow velocity of fluid around a model ship and a propeller in a large cavitation tunnel measured through a 3D LDV device, the focus of different laser beams and The lateral flow rate of the 3D LDV device that allows you to verify the accurate lateral flow rate by comparing the expected lateral flow rate according to the change of the spray angle of water sprayed to the adjacent location and the lateral flow rate measured by the actual 3D LDV device. It is intended to provide a directional flow rate correction device.

The transverse flow velocity correction device of the three-dimensional LDV device according to an embodiment of the present invention is a fixing plate installed on the upper side of a large cavitation tunnel, and installed vertically through the fixing plate, and the laser beam from the inside of the large cavitation tunnel It is provided on one side of the fixed plate and a water spraying portion for spraying water toward the focal point formed by, and an angle adjusting device for changing the angle of the water spraying portion by rotating the water spraying portion clockwise or counterclockwise. have.

In one embodiment, a water injection port through which water is injected is provided at an upper portion of the water injection unit, and a water injection nozzle for spraying the injected water toward a focal point formed by the laser beam is provided at the lower portion. I can.

In one embodiment, the angle adjustment device includes a rotational angle adjustment bolt, and according to the rotation direction of the rotational angle adjustment bolt, the water injection angle of the water injection nozzle is changed in a clockwise or counterclockwise direction. It can be characterized.

In one embodiment, the present invention may further include a pump for supplying water to the water inlet and a flow control device for adjusting the flow rate of the supplied water.

In one embodiment, when the water spray angle of the water spray nozzle is changed by the angle adjusting device, the position of the focal point formed by the laser beam is moved to a position adjacent to the water spray nozzle through the 3D LDV device. It may be characterized in that it is formed by moving.

According to an aspect of the present invention, the lateral flow velocity predicted according to the change in the spray angle of water sprayed at the focal point of the laser beam and the adjacent position and the lateral flow velocity measured by the actual 3D LDV device are compared with each other, and the incident angle It has the advantage of being able to accurately verify the transverse flow velocity obtained only with information such as degrees.

1 is a diagram showing a transverse flow velocity correction apparatus 100 of a 3D LDV apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a state in which the transverse flow velocity correction device 100 of the 3D LDV device shown in FIG. 1 is actually installed in a large cavitation tunnel.
3 is a view showing a state in which the focus of the three-color laser beam is formed at a position adjacent to the water jet nozzle 122 shown in FIG. 1.
FIG. 4 is a view showing a flow velocity vector according to a change in a water spray angle of the water spray nozzle 122 shown in FIG. 1.
FIG. 5 is a table comparing the predicted axial and transverse flow rates predicted based on the flow rate vector of FIG. 4, and actually measured axial and transverse flow rates.

Hereinafter, a preferred embodiment is presented to aid the understanding of the present invention. However, the following examples are provided for easier understanding of the present invention, and the contents of the present invention are not limited by the examples.

FIG. 1 is a diagram showing a transverse flow velocity correction apparatus 100 of a 3D LDV apparatus according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a transverse flow velocity correction apparatus 100 of the 3D LDV apparatus shown in FIG. 1. ) Is actually installed in a large cavitation tunnel.

1 and 2, the transverse flow velocity correction apparatus 100 of a 3D LDV apparatus according to an embodiment of the present invention includes a fixing plate 110, a water spraying unit 120, and an angle adjusting apparatus 130. It consists of including. In addition, in one embodiment, it is configured to additionally include a pump and a flow control device.

The fixing plate 110 is installed on the upper side of a large cavitation tunnel in which a model propeller is installed inside.

The water spray unit 120 is installed to penetrate the center of the fixing plate 110 in a vertical direction, and serves to spray water at a location adjacent to the focus of the laser beam formed by the 3D LDV device inside the large cavitation tunnel. Do it.

Here, the 3D LDV device is based on the focus formed by a plurality of laser beams emitted toward the inside of the large cavitation tunnel in which the model propeller is installed and the scattered light period of particles contained in the fluid in the large cavitation tunnel. It plays a role in calculating the flow velocity of the fluid.

A water injection port 121 for injecting water supplied by a pump is provided in the upper part of the water injection part 120, and a water injection nozzle for injecting the injected water toward the focal point formed by the laser beam. (122) is provided.

At this time, the water jet nozzle 122 takes a shape bent at an angle of 90 degrees to face the length direction of the large cavitation tunnel.

In the water spray nozzle 122, water supplied by the pump is sprayed in the longitudinal direction of the large cavitation tunnel, and water is sprayed while the water is filled in the large cavitation tunnel, and is adjacent to the water outlet of the water spray nozzle 122. The focal point by the three-color laser beam is positioned at the location.

Meanwhile, the angle of the water spray nozzle 122 may be changed in a clockwise or counterclockwise direction by the angle adjusting device 130.

The angle adjusting device 130 is provided on the upper side of the fixing plate 110, and by rotating the water spraying part 120 itself clockwise or counterclockwise, a water spraying nozzle located at the lower end of the water spraying part 120 ( 122) It changes its own angle. At this time, the angle change range of the water spray nozzle 122 by the angle adjustment device 130 is not limited.

This angle adjustment device 130 is configured to include a rotational angle adjustment bolt 131, depending on the rotation direction of the rotational angle adjustment bolt 131, the water injection angle of the water injection nozzle 122 is clockwise or half It changes clockwise.

The pump serves to draw water from the external water storage tank and supply it to the water inlet 121, and the flow control device controls the flow rate of the supplied water.

3 is a view showing a state in which the focus of the three-color laser beam is formed at a position adjacent to the water jet nozzle 122 shown in FIG. 1.

Referring to FIG. 3, it can be seen that a focal point formed by a three-color laser beam is located at a position adjacent to the water outlet of the water jet nozzle 122. The current state is a state in which the water spray nozzle 122 is positioned in the longitudinal direction of the large cavitation tunnel (a state where the angle change is 0°), and if the water spray nozzle 122 rotates clockwise or counterclockwise In this case, the position of the focal point formed by the laser beam is also matched by the 3D LDV device, and the flow velocity vector accordingly is also changed. This point will be described in more detail with reference to FIG. 4.

FIG. 4 is a view showing a flow velocity vector according to a change in a water spray angle of the water spray nozzle 122 shown in FIG. 1.

Referring to FIG. 4, when the water spray angle of the water spray nozzle 122 shown in FIG. 3 is changed, the axial flow rate is U*cosθ (m/s), which is the flow rate of water sprayed by the water spray nozzle 122 , The transverse flow velocity is ±sinθ(m/s). In the present invention, as an embodiment, after measuring the flow rate change by changing the angle of the water spray nozzle 122 clockwise by 20° (referred to as + direction) and counterclockwise by 20° (referred to as-direction) This was compared with the expected axial flow rate and the lateral flow rate, which will be described with reference to FIG.

FIG. 5 is a table comparing the predicted axial and transverse flow rates predicted based on the flow vector of FIG. 4, and actually measured axial and transverse flow rates.

Referring to FIG. 5, when the angle of the water injection nozzle 122 is 0°, only the axial flow velocity exists, and at this time, the predicted lateral flow velocity is predicted as 0 m/s, but the actual measured lateral flow velocity is 0.06 m/s. As can be seen, it is almost 0m/s.

The measurement process is performed in the case of ±10° and ±20° in clockwise and counterclockwise directions, respectively. After adjusting the injection angle of the water injection nozzle 122, the focus of the three-color laser beam is adjusted through a three-dimensional LDV device. Measurement is performed by moving the position close to the center of the water outlet.

When the angle of the water spray nozzle 122 is 10 degrees, the predicted axial flow velocity is 5.33m/s*cos10°=5.25m/s, and the predicted lateral flow velocity is 5.33m/s*sin10°=0.93m/s to be.

The actual measured axial flow velocity is 5.23m/s and the actual measured lateral flow velocity is 0.96m/s, so it can be verified that accurate flow velocity measurement is being made.

Although the above has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

100: Transverse flow velocity correction device of 3D LDV device
110: fixing plate
120: water spray
121: water inlet
122: water spray nozzle
130: angle adjustment device
131: rotary angle adjustment bolt

Claims (5)

3D to calculate the flow velocity of the fluid based on the focus formed by a plurality of laser beams emitted toward the inside of the large cavitation tunnel in which the model propeller is installed and the scattered light period of particles included in the fluid in the large cavitation tunnel In the transverse flow velocity correction apparatus of a three-dimensional LDV apparatus for correcting the transverse flow velocity of the LDV apparatus,
A fixing plate installed on the upper side of the large cavitation tunnel;
A water spray unit installed in a vertical direction passing through the fixing plate and spraying water from the inside of the large cavitation tunnel toward a focal point formed by the laser beam; And
It is provided on one side of the fixed plate, the angle adjusting device for changing the angle of the water injection unit by rotating the water injection unit in a clockwise or counterclockwise direction; Device.
The method of claim 1,
A water injection port through which water is injected is provided in the upper part of the water injection part, and a water injection nozzle for injecting the injected water toward the focal point formed by the laser beam is provided in the lower part. Transverse flow velocity correction device.
The method of claim 2,
The angle adjusting device,
Including; rotating angle adjustment bolt;
According to the rotation direction of the rotational angle adjustment bolt, the water spray angle of the water spray nozzle is changed in a clockwise or counterclockwise direction, the transverse flow rate correction device of the three-dimensional LDV device.
The method of claim 2,
A pump for supplying water to the water inlet; And
A flow control device for adjusting the flow rate of the supplied water; characterized in that it further comprises, the transverse flow rate correction device of the three-dimensional LDV device.
The method of claim 3,
When the water spray angle of the water spray nozzle is changed by the angle adjusting device, the position of the focal point formed by the laser beam is moved to a position adjacent to the water spray nozzle through the three-dimensional LDV device. A transverse flow velocity correction device for a three-dimensional LDV device, characterized in that.

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