KR102532671B1 - Particle Image Velocimetry Converying Device for Multiple Experimental Channels - Google Patents

Abstract

The present invention relates to a multi-experimental waterway particle imaging velocimeter transfer device which comprises: a first experiment water tank, of which an upper portion is opened, having a storage space storing water therein and having a predetermined depth; a second experiment water tank provided in parallel to the first experiment water tank to enable an upper portion to be opened, having the storage space storing the water therein, and having a predetermined depth; a moving rail provided in a longitudinal direction of the first experiment water tank and the second experiment water tank; and a particle imaging velocimeter unit which can be moved according to the moving rail.

Description

Particle Image Velocimetry Conveying Device for Multiple Experimental Channels}

The present invention relates to a multi-experiment channel particle image velocimetry transfer device, and more particularly, to a multi-experiment channel particle image velocimetry transfer device capable of imaging experimental channels with a particle image velocimetry using a number of experimental channels installed in parallel.

Open channel flow refers to the flow of fluid formed by gravity, and is characterized by having a free water surface in contact with the atmosphere. Representative examples of open channel flow include the flow of rivers that can be easily observed in the natural world, and the flow of water in artificially constructed waterways. When designing or constructing artificial water structures such as waterways, a hydraulic model experiment is conducted in advance using an experimental device that can precisely control various factors, and then the suitability or validity of the design is verified based on the results. process is essential.

At this time, the main measurement item in the hydraulic model experiment can be the flow velocity, and the characteristics of the flow velocity in the open channel flow can be influenced by various factors such as flow rate, water depth, and channel width.

Here, flow velocity refers to the distance (S) that fluid particles move within unit time (dt). A rotational anemometer, a hot wire velocimetry, a Doppler velocimetry, and the like are used as equipment for measuring such flow velocity.

The measurement method using the flow rate measurement equipment listed above has been traditionally used in hydraulic model experiments. It has the disadvantage of having uncertainty in the measured value in contact with the flow. On the other hand, particle image velocimetry, which is currently under continuous technological development, is a non-contact measurement method that does not directly contact the water body as a type of optical measurement method. It has the advantage of being able to measure the flow field for at once.

As for the experimental method for various hydraulic conditions, a device capable of easily transforming the topographical characteristics of the experimental canal and performing the open channel experiment by characteristic is being developed.

For example, there was a multi-node variable inclination number system as disclosed in Korean Patent Registration Publication No. 10-1161410.

However, in the case of the multi-node variable slope canal system, only one can be simulated, so it was difficult to simulate and confirm the control group or other variables due to the nature of the canal with various variables.

For the above reasons, the related field is attempting to develop a device capable of analyzing the flow in an open channel with various variables, but satisfactory results have not been obtained so far.

Republic of Korea Patent Registration No. 10-2373183

The present invention has been proposed to solve the problems of the prior art as described above, and an object of the present invention is to provide a particle image velocimetry transport device with multiple experimental channels capable of photographing experimental channels configured in parallel with the particle image velocimetry.

In order to achieve the above object, the present invention,

A first experimental water tank having an open top, a receiving space for receiving water therein, and having a predetermined length; a second experiment tank provided in parallel to the first experiment tank, formed with an open top, formed with an accommodation space for accommodating water therein, and having a predetermined length; Moving rails provided in the longitudinal direction of the first experiment tank and the second experiment tank; and a particle image velocimetry unit capable of moving along the moving rail. We propose a particle image velocimetry transfer device with a multi-experimental number characterized in that it includes.

The particle image velocity measuring unit may include a base plate movable along the moving rail; a motor capable of driving the base plate; a fixing jig provided on the base plate and capable of fixing the particle image velocimetry to one of the first experimental tank and the second experimental tank; a laser light source device provided on the base plate and radiating a laser to one of the first experimental tank and the second experimental tank; and a reflector provided under one of the first experiment tank and the second experiment tank to reflect the laser beam of the laser light source device in a vertical direction. can include

The base plate further includes a blackout portion capable of covering the first experiment tank and the second experiment tank according to the movement of the base plate, wherein the shade portion can cover the first experiment tank and the second experiment tank a blackout frame provided on the base plate to support the blackout frame;

a plurality of blackout rails provided adjacent to the first experimental tank and the second experimental tank and capable of transporting the blackout frame; can include

Here, a controller capable of controlling the particle image velocity measuring unit may be further included.

Three surfaces of the first experimental tank and the second experimental tank may be formed of low iron glass.

The present invention proposes to provide a particle image velocimetry transfer device with multiple experimental channels capable of photographing experimental channels configured in parallel with particle image velocimetry for analysis of flow in open channels.

1 is a schematic diagram showing the overall structure of the particle image velocimetry transfer device with multiple experimental numbers according to the present invention.
2 is a detailed view of the particle image velocimetry unit of the particle image velocimetry transfer device with multiple experimental numbers according to the present invention.
3 is a detailed view of the dark part of the particle image velocimetry transport device with multiple experimental water channels according to the present invention.
4 is an exemplary view applied to the transfer jig of the particle image velocimetry transfer device with multiple experimental numbers according to the present invention.
5 is an exemplary view to which a variable arm is applied to the particle image velocimetry transport device with multiple experimental numbers according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

As shown in FIG. 1, the particle image velocimetry transfer device (A) with multiple experimental waters according to the present invention includes a first experimental tank 100, a second experimental tank 150, a moving rail 200, and a particle image velocimeter. Includes section 300 .

The first experimental water tank 100 of the present invention is formed with an open top, a receiving space for receiving water is formed therein, and may have a certain length.

At this time, the second experiment water tank 150 is provided in parallel with the first experiment water tank 100 so as to have an open top, a receiving space for receiving water is formed therein, and may have a certain length.

Here, the first experimental tank 100 and the second experimental tank 150 can simulate various conditions by having different capacities.

At this time, the first experimental tank 100 and the second experimental tank 150 may be formed of low iron glass on three sides as an embodiment.

The moving rail 200 of the present invention is provided between the first experiment tank 100 and the second experiment tank 150, and the particle image velocity measuring unit 300 may be provided.

As shown in FIG. 2, the particle image velocimetry unit 300 of the present invention may be provided with a base plate 310 that can move along the moving rail 200.

At this time, a motor 320 capable of driving the base plate 310 may be provided.

Here, various means capable of driving the base plate 310 may be used in addition to the motor 320 .

In addition, as long as the base plate 310 is driven by the motor 320 and can move along the movable rail 200, it may be of any conventional structure and method.

At this time, the controller 500 may control the motor 320 according to the speed required for imaging of the particle image velocimetry 50 .

Here, the fixing jig 330 is provided on the base plate 310 to fix the particle image velocimetry 50 so that one of the first experimental tank 100 and the second experimental tank 150 can be photographed.

At this time, by separating the fixing jig 330, the operator can change the position close to the first experiment tank 100 or the second experiment tank 150.

Here, the base plate 310 is provided with a laser light source device 350, and irradiates a laser, which is a light source required for photographing the particle image velocimetry 50, to one of the first experimental tank 100 and the second experimental tank 150. can do.

At this time, a reflector 360 is provided under one of the first experimental tank 100 and the second experimental tank 150 to reflect the laser of the laser light source device 350 in a vertical direction, so that the first experimental tank ( 100) or the fine particles in the second experimental tank 150 are irradiated with a laser, and the particles are photographed and analyzed by the particle image velocimetry 50, so the flow in the open channel can be analyzed.

Here, the vicinity of the first experimental tank 100, the second experimental tank 150, and the base plate 310 should be maintained in a state in which light is blocked as much as possible for more precise measurement and photographing.

Thus, a blackout portion 400 capable of covering the first experimental water tank 100 and the second experimental water tank 150 according to the movement of the base plate 310 may be further included.

At this time, the blackout unit 400 may include a blackout 410, a blackout frame 420, and a blackout rail 430, as shown in FIG.

Here, the blackout 410 can cover the first experimental tank 100 and the second experimental tank 150 and cover the base plate 310 between the first experimental tank 100 and the second experimental tank 150. can

At this time, the area of the blackout 410 may be variously modified according to the design and is not limited thereto.

At this time, the blackout frame 420 may be provided on the base plate 310 to support the blackout 410 .

Here, the blackout frame 420 may be transported along the blackout rail 430 .

In this case, a plurality of blackout rails 430 may be provided near the first experiment tank 100 and the second experiment tank 150 .

In addition, the particle image velocimetry unit 300 according to the present invention may additionally include a transfer jig 340 .

At this time, the transfer jig 340 may move the position of the particle image velocimetry 50 up, down, left and right as shown in FIG. 4 .

Here, as an embodiment of the transfer jig 340, it can be transferred to an LM guide (not shown in the drawing).

In addition, the transfer jig 340 is located at the center of the base plate 310, has a turntable 345, and the particle image velocimetry 50 may be coupled to the turntable 345.

Thus, when the first experimental tank 100 or the second experimental tank 150 is photographed with the particle image velocimetry 50 as the turntable 345 rotates, the photograph can be taken without separating the transfer jig 340.

Additionally, the particle image velocimetry unit 300 according to the present invention may further include a variable arm 370 .

Here, as shown in FIG. 5, the variable arm 370 is provided on the base plate 310 and expands or contracts the reflector 360 to either the first experimental water tank 100 or the second experimental water tank 150. It can be located in the lower center of the .

In addition, the extension or contraction of the variable arm 370 may be controlled by the controller 500 as an example.

At this time, as another embodiment, a calibration sensor (not shown in the drawing) is connected to the controller 500 to measure the position and distance of the reflector 360 to lower the first experimental tank 100 or the second experimental tank 150. The length of the variable arm 370 may be adjusted so that the laser is irradiated to the center of the .

Since the present invention as described above is not limited to the above-described embodiments, it can be modified within the scope not departing from the gist of the present invention claimed in the claims, and such changes are defined by the description of the claims below. fall within the protection scope of the invention.

10: flow rate supply tank 50: particle image velocimetry
100: first experimental tank 150: second experimental tank
200: moving rail 300: particle image velocity measurement unit
310: base plate 320: motor
330: fixed jig 340: transfer jig
345: turntable
350: laser light source device 360: reflector
370: variable arm 400: dark part
410: blackout 420: blackout frame
430: blackout rail 500: controller

Claims (13)

delete delete delete delete delete A first experimental water tank having an open top, a receiving space for receiving water therein, and having a predetermined length;
a second experiment tank provided in parallel to the first experiment tank, formed with an open top, formed with an accommodation space for accommodating water therein, and having a predetermined length;
Moving rails provided in the longitudinal direction of the first experiment tank and the second experiment tank; and
A particle image velocity measuring unit moving along the moving rail and photographing one of the first experimental tank and the second experimental tank;
The particle image velocity calculator
a base plate movable along the movable rail;
a motor capable of driving the base plate;
a transfer jig provided on the base plate and capable of transferring the position of the particle image velocimeter vertically and horizontally;
a laser light source device provided on the base plate and radiating a laser to one of the first experimental tank and the second experimental tank; and
A reflector provided under one of the first experimental tank and the second experimental tank to reflect the laser of the laser light source device in a vertical direction,
The transfer jig,
A turntable to which the particle image velocimetry is coupled,
Particle image velocimetry transfer device with multiple experimental water, characterized in that the first experimental tank or the second experimental tank can be photographed by the particle image velocimetry according to the rotation of the turntable.
According to claim 6,
Further comprising a blackout portion provided on the base plate and capable of covering the first experimental tank and the second experimental tank according to the movement of the base plate,
The darkening part,
a blackout screen capable of covering the first experimental tank and the second experimental tank;
a blackout frame provided on the base plate and capable of supporting the blackout;
A plurality of blackout rails provided adjacent to the first experimental tank and the second experimental tank and capable of transporting the blackout frame;
Particle image velocimetry transfer device with a multi-experimental number, characterized in that it comprises.
According to claim 6,
Particle image velocimetry transfer device with multiple experimental numbers, characterized in that it further comprises a controller capable of controlling the particle image velocimetry unit.
According to claim 6,
Particle image velocimetry transfer device with multi-experiment water, characterized in that the first experiment tank and the second experiment tank are formed of low iron glass on three sides.
A first experimental water tank having an open top, a receiving space for receiving water therein, and having a predetermined length;
a second experiment tank provided in parallel to the first experiment tank, formed with an open top, formed with an accommodation space for accommodating water therein, and having a predetermined length;
Moving rails provided in the longitudinal direction of the first experiment tank and the second experiment tank; and
A particle image velocity measuring unit moving along the moving rail and photographing one of the first experimental tank and the second experimental tank;
The particle image velocity calculator
a base plate movable along the movable rail;
a motor capable of driving the base plate;
a transfer jig provided on the base plate and capable of transferring the position of the particle image velocimeter vertically and horizontally;
a laser light source device provided on the base plate and radiating a laser to one of the first experimental tank and the second experimental tank;
a reflector provided under one of the first experiment tank and the second experiment tank to reflect the laser beam of the laser light source device in a vertical direction; and
A variable arm provided on the base plate and capable of positioning the reflector at the lower center of one of the first experimental tank and the second experimental tank by extension or contraction,
The transfer jig,
A turntable to which the particle image velocimetry is coupled,
Particle image velocimetry transfer device with multi-experiment water, characterized in that the first experiment tank or the second experiment tank can be photographed by the particle image velocimetry according to the rotation of the turntable.
According to claim 10,
Further comprising a blackout portion provided on the base plate and capable of covering the first experimental tank and the second experimental tank according to the movement of the base plate,
The darkening part,
a blackout screen capable of covering the first experimental tank and the second experimental tank;
a blackout frame provided on the base plate and capable of supporting the blackout;
A plurality of blackout rails provided adjacent to the first experimental tank and the second experimental tank and capable of transporting the blackout frame;
Particle image velocimetry transfer device with a multi-experimental number, characterized in that it comprises.
According to claim 10,
Particle image velocimetry transfer device with multiple experimental numbers, characterized in that it further comprises a controller capable of controlling the particle image velocimetry unit.
According to claim 10,
Particle image velocimetry transfer device with multi-experiment water, characterized in that the first experiment tank and the second experiment tank are formed of low iron glass on three sides.

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