KR101206242B1 - Anemometer and method for measuring wind speed - Google Patents

Abstract

An anemometer is disclosed. The anemometer is a frame body having a space formed therein, a fan shaft located at the center of the space, and one side is supported by the frame body, the other side is supported by a frame, a fan shaft including a fan shaft support for supporting the fan shaft, the fan shaft It may include a fan that rotates, a rotation shaft extending outward from the frame body, and a support part rotatably supporting the rotation shaft so that the fan faces the wind direction.

Description

Anemometer and wind speed measurement method {ANEMOMETER AND METHOD FOR MEASURING WIND SPEED}

The present invention relates to an anemometer, and more particularly, to an anemometer including a fan and a wind speed measuring method.

In general, an anemometer is a device for measuring wind speed at a location where wind is generated.

An anemometer may include a fan that rotates as the wind passes, and an anemometer containing such a fan can measure an accurate measurement of the wind speed as it faces the direction of the wind's flow, that is, when the air flow and the fan remain orthogonal. have. An anemometer with a fan, on the other hand, measures a distorted measurement of wind speed when the airflow and the fan do not maintain orthogonality.

On the other hand, in the position where the wind flows into the fan at various angles, it is very difficult to maintain the orthogonality of the anemometer and the air flow at each measuring point using the anemometer. There is a problem that the measured values of are different from each other.

One embodiment of the present invention may provide an anemometer and a wind speed measuring method capable of measuring the same wind speed even if the wind is introduced at various angles.

The first aspect of the present invention is a frame body having a space formed therein, a fan shaft located in the center of the space and one side is supported on the frame body, the other side of the frame including a fan shaft support for supporting the fan shaft, in the space An anemometer, supported by the fan shaft, comprising a fan that rotates about the fan shaft, a rotation shaft extending outward from the frame body, and a support part rotatably supporting the rotation shaft so that the fan faces the wind direction. To provide.

It may further include a measuring device connected to the fan shaft and measuring the wind speed based on the rotational speed of the fan.

The support part includes a support part body into which the rotation shaft is inserted, a fixed shaft spaced apart from the rotation shaft, and positioned on the concentric shaft with the rotation shaft in the support body, a coil surrounding the rotation shaft and the fixed shaft in the support body, and the coil. Is located in, one side is coupled to the rotary shaft, the other side may include a rotor coupled to the fixed shaft and structurally coupled to the rotary shaft or the fixed shaft.

Each of the rotating shaft and the fixed shaft and the rotor may be screwed.

When the wind speed measured by the measuring instrument is the maximum, it may further include a control unit for controlling the rotation of the rotary shaft to be fixed to the support for a predetermined time.

In addition, the second aspect of the present invention provides a step of providing the anemometer, setting a set time for measuring the wind speed, measuring the wind speed using the anemometer during the set time, the highest of the wind speed measured during the set time It provides a wind speed measuring method comprising the step of storing the rotation angle of the rotary shaft according to the wind speed and measuring the wind speed for a predetermined time by rotating the rotary shaft at the rotation angle.

According to one of the embodiments of the present invention, there is provided an anemometer and a wind speed measuring method capable of measuring the same wind speed even if the wind is introduced at various angles.

1 is a view showing an anemometer according to a first embodiment of the present invention.
FIG. 2 is a view of the anemometer shown in FIG. 1 from above.
3 and 4 are views illustrating part A of FIG. 1.
5 is a flowchart illustrating a wind speed measuring method according to a second embodiment of the present invention.

Hereinafter, an anemometer according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 4.

1 is a view showing an anemometer according to a first embodiment of the present invention.

As shown in FIG. 1, an anemometer according to a first embodiment of the present invention is an apparatus for measuring wind speed, and includes a first frame 100, a fan 200, a rotation shaft 300, a second frame 400, It may include a support 500, a meter 600, and a control unit 700.

The first frame 100 may include a frame body 110, a fan shaft support 120, and a fan shaft 130.

Frame body 110 is formed in a circular shape, the space (S) is formed inside. The fan shaft support 120, the fan shaft 130, and the fan 200 are positioned in the space S formed by the frame body 110.

The fan shaft supporter 120 connects between the fan shaft 130 and the frame body 110, and one side of the fan shaft support 120 is supported by the frame body 110 while the other side supports the fan shaft 130.

The fan shaft 130 is located at the center of the space S and supports the fan 200.

The fan 200 is supported by the fan shaft 130 in the space S, and may rotate in rotation about the fan shaft 130. When the wind flows into the space S, the fan 200 is rotated by the wind about the fan shaft 130.

The rotating shaft 300 is connected to the frame main body 110 and extends from the frame main body 110 in the direction of the support part 500 that is outward. The rotating shaft 300 is supported by the support part 500 so as to be freely rotatable with respect to the support part 500, and a detailed form will be described later.

The support part 500 supports the rotation shaft 300 so that the rotation shaft 300 can rotate by itself, and thus the fan 200 can rotate to face the wind direction of the wind.

FIG. 2 is a view of the anemometer shown in FIG. 1 from above.

More specifically, as shown in FIGS. 1 and 2, the fan shaft 130, the fan shaft support 120, the first frame 100, and the rotation shaft 300 are interconnected to each other, and the fan shaft 130 is centered. In the state in which the fan 200 is supported by the fan shaft 130 so that the fan 200 rotates, the rotation shaft 300 is supported by the support 500 so as to be rotatable with respect to the support 500. When the wind is introduced into the space (S) formed by the 100, the fan 200 is rotated to face the wind direction in the direction of the wind, as the fan 200 rotates the fan shaft 130, the fan shaft support 120 ), The first frame 100 and the rotating shaft 300 is rotated. That is, since the rotating shaft 300 is supported by the support 500 so as to be rotatable with respect to the support 500, the fan 200 may face the wind direction.

The fan shaft 130, the fan shaft support 120, the first frame 100, and the rotation shaft 300 may be integrally formed or interconnected.

The second frame 400 surrounds the edge of the first frame 100 and may serve to protect the first frame 100 and the fan 200 from an external impact.

3 and 4 are views illustrating part A of FIG. 1.

As shown in FIGS. 3 and 4, the support part 500 may include a support body 510, a fixed shaft 520, a coil 530, and a rotor 540.

The support body 510 is cylindrical having a space formed therein, and a part of the rotation shaft 300 is inserted into the space therein.

The fixed shaft 520 is spaced apart from the rotating shaft 300 while being positioned on the concentric shaft with the rotating shaft 300 in the inner space of the support body 510. A fixed shaft male screw 521 is formed on a surface of an end of the fixed shaft 520, and a rotating shaft male screw 310 is formed on a surface of an end of the rotary shaft 300.

The coil 530 surrounds at least a portion of the rotation shaft 300 and the fixed shaft 520 in the inner space of the support body 510, and current flows through the coil 530 to induce rotation of the rotor 540. can do.

The rotor 540 is located in an inner region surrounded by the coil 530 and is structurally coupled to the rotating shaft 300 or the fixed shaft 520. More specifically, as shown in Figure 3, the rotor female screw 541 formed inside the rotor 540 and the fixed shaft male screw 521 formed on the surface of the fixed shaft 520 are mutually coupled to the fixed shaft ( 520 and the rotor 540 may be screwed to each other structurally. In this case, the rotation shaft 300 is supported to be freely rotatable with respect to the support 500. In addition, as shown in FIG. 4, the rotor female screw 541 formed in the rotor 540 by rotating the rotor 540 in the first direction and the rotating shaft male screw 310 formed on the surface of the rotating shaft 300. ) Is coupled to each other, the rotating shaft 300 and the rotor 540 may be screwed to each other structurally. In this case, the rotation shaft 300 is locked to the rotor 540 so that the rotation shaft 300 is fixed to the support part 500, and the rotation angle of the rotation shaft 300 is changed according to the rotation speed of the rotor 540. The fan 200 is rotated and fixed according to the rotation angle of the rotation shaft 300. That is, the rotation angle of the fan 200 may depend on the rotation speed of the rotor 540.

The operation of the rotor 540 may be controlled according to the amount and direction of current flowing through the coil 530 surrounding the rotor 540. More specifically, the rotor 540 is controlled in the number of revolutions of the rotor 540 according to the amount of current flowing in the coil 530, the rotation of the rotor 540 in accordance with the direction of the current flowing in the coil 530 The direction is controlled. The rotor 540 may be formed of a magnet, and the amount and direction of current flowing through the coil 530 are controlled by the controller 700 to be described later.

Referring back to FIG. 1, the measuring device 600 is electrically connected to the fan shaft 130, and the first frame 100 is formed based on the rotational speed of the fan 200 rotating around the fan shaft 130. The wind speed of the wind passing through the space S can be measured. The measuring device 600 may include a display device and may display the measured wind speed to the outside through the display device.

In addition, the measuring device 600 according to the embodiment of the present invention may be connected to the rotating shaft 300, and may transmit the rotation angle of the rotating shaft 300 when the wind speed is maximum to the controller 700 to be described later.

The controller 700 may control the rotation of the rotation shaft 300 such that the rotation shaft 300 is fixed to the support part 500 when the wind speed measured by the measuring device 600 is the maximum. In more detail, the control unit 700 stores the rotation angle of the rotation shaft 300 when the wind speed of the wind passing through the space S formed by the first frame 100 is the maximum, and the rotation shaft 300 is the rotation angle. The rotor 540 is structurally coupled to the rotating shaft 300 by sending a current to the coil 530 so as to be fixed to the rotating shaft 300 to fix the support 500. That is, the controller 700 controls the rotation of the rotating shaft 300 by using the coil 530 and the rotor 540, and the wind speed of the wind passing through the space S formed by the first frame 100 is the maximum. When the rotating shaft 300 is fixed at a rotation angle at the time, the measuring device 600 measures the wind speed of the wind.

In the present exemplary embodiment, the measuring device 600 measures the rotation angle of the rotation shaft 300 when the wind speed is the maximum, and transmits it to the control unit 700.

However, the present invention is not limited to this.

For example, according to the environment to which the present invention is applied, the control unit 700 is connected to the rotation shaft 300 to measure the rotation angle when the wind speed is maximum, and as described above, the rotation shaft 300 at the measured rotation angle Can control the rotation.

Hereinafter, the wind speed measuring method according to the second embodiment of the present invention will be described with reference to FIG. 6.

6 is a flowchart illustrating a wind speed measuring method according to a second embodiment of the present invention.

As shown in FIG. 6, first, an anemometer may be provided (S100).

Specifically, it is possible to provide an anemometer according to the first embodiment of the present invention described above.

Next, a set time may be set (S200).

In detail, in the state in which the rotating shaft 300 is rotatably supported with respect to the support part 500, a set time for measuring the wind speed of the wind flowing through the space S formed by the first frame 100 may be set.

The step (S200) of setting the time for measuring the wind speed may be omitted in the wind speed measuring method after that, once the correction is not necessary for the measurement time.

Next, the wind speed may be measured during the set time (S300).

Specifically, the first frame (in the state in which the rotating shaft 300 is rotatably supported with respect to the support 500 using an anemometer, that is, the rotor 540 is coupled to the fixed shaft 520 in the support 500. The wind speed of the wind flowing through the space S formed by 100 may be measured for a predetermined time. At this time, the fan 200 is rotated in a direction facing the wind direction, which is the direction of the wind, and based on the rotational speed of the fan 200, the measuring device 600 measures the wind speed of the wind flowing through the space S for a predetermined time. Done.

Next, the rotation angle of the rotating shaft 300 according to the highest wind speed of the measured wind speed can be stored (S400).

Specifically, in a state in which the rotation shaft 300 is rotatably supported with respect to the support part 500, the rotation angle of the rotation shaft 300 according to the highest wind speed among the wind speeds measured by the measuring device 600 is stored for a set time. The control unit 700 stores a signal indicating the rotation angle of the rotation shaft 300 by transmitting the signal 600 indicating the rotation angle of the rotation shaft 300 to the controller 700 by being connected to the rotation shaft 300. 700 may generate and store a signal indicating a rotation angle of the rotation shaft 300. Although not shown, a signal indicating the rotation angle of the rotation shaft 300 may be stored in a storage unit connected to the control unit 700.

Next, the wind speed may be measured for a predetermined time by rotating the rotating shaft 300 at a rotation angle (S500).

Specifically, in a state in which the rotating shaft 300 is rotatably supported with respect to the support part 500, the control unit 700 extracts a signal indicating the rotation angle of the rotating shaft 300 according to the highest wind speed from the storage unit and according to the signal. When the current flows through the coil 530, the rotor 540 moves while rotating in the first direction in which the rotating shaft 300 is positioned while being coupled to the fixed shaft 520 to be coupled to the rotating shaft 300. At this time, while the rotor 540 is coupled to the rotating shaft 300, the rotating shaft 300 is fixed to the support part 500, and the rotating shaft 300 is rotated by the rotation angle to which the rotor 540 is finally fixed, thereby supporting the supporting part ( 500). For this reason, the rotating shaft 300 is rotated at the rotation angle at the highest wind speed of the measured wind speed during the set time, the rotation shaft 300 is rotated by the fan 200 supported by the fan shaft 130 is also at the highest wind speed It is rotated by the rotation angle.

Thereafter, the fan 200 rotates according to the wind passing through the space S formed by the first frame 100, and the measuring device 600 adjusts the wind speed for a predetermined time based on the rotation speed of the fan 200. It can be measured.

As described above, the anemometer measures the wind speed, and the wind speed is measured for a predetermined time in a state in which the rotating shaft 300 is rotated at the rotation angle of the rotating shaft 300 at the highest wind speed. Even when flowing into the space S formed by the first frame 100, the same wind speed may be measured. For this reason, even if the person measuring the wind speed using the anemometer is different, the same wind speed may be measured at the same position, which may act as a factor of improving the reliability of the wind speed measurement using the anemometer.

As such, the anemometer according to the first embodiment of the present invention and the wind speed measuring method according to the second embodiment using the anemometer improve the reliability of the wind speed measurement at the same position where the wind speed is to be measured.

Although the present invention has been described through the preferred embodiments as described above, the present invention is not limited thereto and various modifications and changes can be made without departing from the spirit and scope of the claims set out below. Those in the technical field to which they belong will easily understand.

First frame 100, the fan 200, the rotating shaft 300, the support portion 500

Claims (6)

A frame including a frame body having a space formed therein, a fan shaft positioned at the center of the space, and one side of which is supported by the frame body, and the other side of which supports the fan shaft;
A fan supported by the fan shaft in the space and rotating around the fan shaft;
A rotating shaft extending outward from the frame body; And
Support for rotatably supporting the rotating shaft so that the fan facing the wind direction
Including;
The support portion
A support unit body into which the rotation shaft is inserted;
A fixed shaft spaced apart from the rotation shaft and positioned on the concentric shaft with the rotation shaft in the support body;
A coil surrounding the rotating shaft and the fixed shaft in the support body; And
Is located in the coil, one side is coupled to the rotating shaft, or the other side is coupled to the fixed shaft and the rotor is structurally coupled to the rotating shaft or the fixed shaft
Anemometer comprising a.
The method of claim 1,
An anemometer further connected to the fan shaft and measuring a wind speed based on the rotational speed of the fan.
delete The method of claim 1,
An anemometer for screwing each of the rotating shaft and the fixed shaft and the rotor.
The method of claim 2,
And a controller configured to control the rotation of the rotation shaft such that the rotation shaft is fixed to the support part for a predetermined time when the wind speed measured by the measuring instrument is maximum.
Providing an anemometer according to any one of claims 1, 2, 4 and 5;
Measuring wind speed using the wind speed meter for a predetermined set time;
Storing the rotation angle of the rotation shaft according to the highest wind speed among the wind speeds measured during the set time; And
Measuring the wind speed for a predetermined time by rotating the rotary shaft at the rotation angle.
Wind speed measuring method comprising a.

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