KR101417716B1 - Anemometer with enhanced accuracy - Google Patents

Abstract

The objective of the present invention is to provide an anemometer capable of measuring the wind speed accurately by receiving sufficient rotatory power even in the case of gentle wind. To achieve the objective, the anemometer includes: a body; a shaft which is combined to the body and installed vertically; a rotating body which is combined to the shaft by a bearing and is rotatable around the shaft; and rotor blades which are placed outside the rotating body, are combined to the rotating body by a support, rotate the rotating body by receiving wind in a direction vertical to the longitudinal direction of the shaft, and have a vessel shape. The anemometer further includes: a measurement unit which is combined to the body and measures the number of rotations. An odd number, equal to or greater than four, of rotor blades are installed at regular intervals around the shaft and are installed for every concave direction to be in the same rotation direction around the shaft. Among the rotor blades, rotor blades installed higher than the average height and rotor blades installed lower than the average height are placed alternately.

Description

Anemometer with enhanced accuracy Anemometer with improved measurement accuracy

The present invention relates to an anemometer with improved measuring accuracy, and more particularly, to an anemometer configured to be able to measure wind speed even in fine wind by alternately locating upper and lower sides of a rotary vane in the form of a hollow container so as to receive wind power without being interfered with each other will be.

Since the wind speed has an important influence on the real life, more accurate measurement becomes necessary as the mode of life becomes various and complicated.

Figs. 1 to 3 are conventional anemometers disclosed in Korean Utility Model Registration No. 20-0447503, which shows an anemometer for measuring the speed of rotation by a rotary vane and measuring the wind speed.

1 and 2, the anemometer includes a supporting shaft 2, a bearing and a rotating body 3 provided in order at the upper end of the supporting shaft 2, and an outer side of the rotating body 3 A plurality of rotary vanes 1a to 1d are installed. The sensor 8a is disposed in the inner space of the rotary cover 4 integrally coupled to the lower portion of the rotary body 3 and the sensing unit 8b is installed in the rotary cover 4. [

Accordingly, the rotary vanes 1a to 1d are installed radially outside the rotating body 3 and rotate together with the rotating body 3 by the wind. The sensor 8a senses the sensing portion 8b when the sensing portion 8b passes close to the upper portion of the sensor 8a as the rotation cover 4 rotates, ) Can be detected by being made of magnet or the like.

However, in the above-described conventional anemometer, four rotary blades 1a to 1d having a container shape are provided and all have the same height, so that they can be interfered with each other when receiving wind power.

2, which shows the rotary vanes 1a to 1d viewed from the wind direction side, the rotary vane 1c, which is required to rotate the shaft by receiving wind power, is shrouded by the rotary vane 1d, , The wind force received by the rotary blade of the reference numeral 1c mainly contributes to the rotational force, and the degree of contribution of the rotary blade of the reference numeral 1d to the rotational force becomes small.

Accordingly, the rotational force generated by the rotating blades is weak with respect to the small wind force, so that rotation around the shaft 2 is hard to occur, and the measured value for the minute wind speed can not be accurately output.

3, minute intervals 5, 6 are formed at the lower end of the rotary cover 4 during wind generation to allow air to flow into and out of the inner space 7 of the rotary cover.

Rainwater flows into the minute gap 5 during rainfall or foreign matter such as dust is introduced to cause a failure of the electronic device installed inside. The foreign matter sticks between the shaft 2 and the rotating body 3 and rotates Sometimes it interferes.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an anemometer capable of precisely measuring the wind speed by receiving sufficient rotational force against a minute wind speed.

It is another object of the present invention to provide an anemometer of a structure which can prevent rainwater or foreign matter from flowing into the internal space, thereby preventing the occurrence of faults in electronic devices such as sensors and rotation of the rotating body.

According to an aspect of the present invention, there is provided a portable electronic device including a body, a shaft vertically coupled to the body, a rotating body coupled to the shaft via a bearing and rotatable about the shaft, And a rotatable blade having a recessed shape which is located on the outer side of the rotating body and rotates by receiving wind in a direction perpendicular to the longitudinal direction of the shaft, Wherein the rotary wing is provided with four or more even-numbered teeth arranged at equal intervals around the shaft, wherein all the recessed wings are arranged in the same rotation direction And the rotary vane is provided with a rotary vane installed above the average height of the rotary vanes and an average The supporting members are integrally formed with each other, and the supporting member is formed integrally with the supporting member, and the supporting member is extended radially outwardly so that the upper and lower supporting members are alternately formed, And the position of the blade is set.
Further, in the present invention, the rotary blades provided above the average height are all the same height, and the rotary blades provided below the average height are all the same height, and the bearings are installed between the shaft and the rotating body Wherein a radial bearing and a thrust bearing are integrally formed on a lower side of the thrust bearing so that the shaft supports the thrust bearing so that a vertical load of the rotary body through the thrust bearing And the shaft is supported by the shaft.
According to another aspect of the present invention, there is provided a motor vehicle including a body, a shaft vertically installed at an upper end of the body, a bearing mounted on the shaft, a rotatable body coupled to the bearing and freely rotatable about the shaft, And a pair of support members which are respectively coupled to the ends of the four support members to receive winds in a direction perpendicular to the longitudinal direction of the shaft, And a measuring unit coupled to the body for measuring the number of revolutions of the rotating body, wherein the measuring unit measures the number of revolutions of the rotating body, The supports are integrally formed and extend radially outward so that they are bent upwardly and downwardly, By being formed and being arranged alternately be positioned on the lower side that is located above the four rotary blades.
In addition, the present invention is characterized in that the upper one of the four rotary blades is a pair which is rotationally symmetric about the shaft as a rotational center, and the pair of the rotational pairs are rotationally symmetric about the shaft Wherein the bearing includes a radial bearing and a roller bearing disposed between the shaft and the rotating body, and the shaft is integrally formed with an annular bearing portion on the lower side of the roller bearing so as to support the roller bearing And the vertical load of the rotating body is supported by the shaft via the thrust bearing.
Further, the present invention is characterized in that the rotating body has a rotationally symmetrical shape with the shaft as a center, covers the upper part of the body with an interval, and the outer side of the inner space formed between the inner surface of the rotating body and the upper part of the body Wherein a minimum clearance between the rotating body and the body is formed in an annular shape along the circumference of the rotating body, and a protrusion for generating a turbulent flow in the minimum interval portion when the rotating body rotates is provided on the inner surface of the rotating body And a plurality of portions are formed along the circumference.
The present invention is characterized in that the projections are formed at the inner space side of the minimum space portion on the inner surface of the rotating body and a plurality of them are arranged at regular intervals along the circumference of the rotating body so as to form an annular trajectory as a whole .

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The anemometer according to the present invention as described above can receive the wind power generating the rotational force without being interfered with each other by arranging the upper and lower rotary vanes alternately in the rotating direction around the shaft.

Therefore, the anemometer of the present invention can generate a relatively large rotational force by receiving sufficient wind power as compared with the conventional anemometer, so that the rotary vane of the anemometer can rotate about the shaft even at a minute wind speed. This makes it possible to measure the wind speed more precisely than in the past.

In the present invention, a plurality of protrusions are disposed on the inner surface of the rotating body so as to generate turbulence in the minimum space portion connecting the inner space and the outside, thereby disturbing the surrounding air while rotating the rotating body, So as to generate turbulence. Accordingly, the turbulence formed in the minimum clearance serves as an air curtain, thereby blocking the inflow of rainwater or foreign matter into the internal space, thereby causing trouble in electronic devices such as sensors, So that the problem of hindering the rotation can be solved.

1 is a perspective view showing an external configuration of a conventional anemoscope.
Fig. 2 is a structural explanatory view showing the vane arrangement and internal configuration of the anemometer of Fig. 1
3 is an explanatory view for explaining the problem of the foreign matter flowing into the internal space of the anemometer of FIG.
4 is an exploded perspective view of an anemometer according to an embodiment of the present invention.
5 is a front view of an anemometer according to an embodiment of the present invention.
6 is a cross-sectional view of an anemometer according to an embodiment of the present invention
FIG. 7 is a front view of the anemometer according to the embodiment of the present invention, viewed from the direction of the wind direction, showing a state in which the rotating blades are rotated about the shaft by receiving wind power
FIG. 8 shows an anemometer according to another embodiment of the present invention. The front view of an anemometer in which six rotary vanes are arranged at intervals of 60 degrees
FIG. 9 shows an anemometer according to another embodiment of the present invention. FIG. 9 is a plan view of an anemometer in which six rotary vanes are arranged at intervals of 60 degrees
FIG. 10 shows an anemometer according to another embodiment of the present invention. FIG. 10 is a plan view showing an anemometer in which eight rotary vanes are arranged at intervals of 45 degrees
11 is a perspective view showing a configuration in which projections are formed inside the rotating body;
FIG. 12 is an explanatory view explaining an action of generating a turbulent flow by disturbing the surrounding air at the minimum space between the rotating body and the body;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 4 is an exploded perspective view of an anemoscope according to an embodiment of the present invention, FIG. 5 is a front view of an anemometer according to an embodiment of the present invention, and FIG. 6 is a sectional view of an anemometer according to an embodiment of the present invention.

4 to 6, an anemometer according to an embodiment of the present invention includes a body 10, a shaft 20 vertically coupled to the body 10, a shaft 20 mounted on the shaft 20, The rotating body 40 is rotatably supported by the supporting body 51-54 at the outer side of the rotating body 40. The rotating body 40 is rotatably supported by the supporting body 51-54, And a rotatable blade 61-64 in the form of a hollow container for rotating the rotator 40 in response to the wind in the direction perpendicular to the longitudinal direction of the shaft 20. [

The body 10 supports the shaft 20, the rotating body 40, and the like. The body 10 is formed in a cylindrical shape, and a connecting line for transmitting a signal detecting the wind speed is installed in the body 10.

The shaft 20 is installed vertically in the center of the body 10. The shaft 20 serves as a rotating shaft of the rotating body 40 in a stopped state without rotating.

A bearing 30 is provided between the inner surface of the rotating body 40 and the shaft 20 so that the shaft 20 is rotatably supported by the shaft 20. The shaft 20 is provided with a structure in which the rotating body 40 covers the shaft 20 from above. The free rotation of the rotating body 40 is possible.

The bearing 30 is provided with the roller bearing 32 together with the radial bearing 31 so that the vertical load of the rotating body 40 is supported by the shaft 20 to enable smooth rotation of the rotating body 40 And the shaft 20 is formed integrally with the annular support portion 23 on the lower side of the thrust bearing 32 so as to support the thrust bearing 32. [

The rotating body 40 is coupled to the shaft 20 through a bearing 30 so as to be freely rotatable, and a supporting body for supporting the rotating blades 61-64 is coupled.

The rotating body 40 is coupled to the shaft 20 from above in such a manner as to cover the shaft 20 and covers the upper portion of the body 10 at a lower portion of the rotating body 40. However, since the rotating body 40 must rotate freely, it is spaced from the body 10.

A measuring means for measuring the number of revolutions of the rotating body 40 by forming an internal space 72 between the rotating body 40 and the upper portion of the body 10 in a state where the rotating body 40 is installed 14 are installed.

The measuring means 14 is a magnetic force sensor which is coupled to the upper portion of the body 10 in the internal space 72. The magnetic force sensor senses the number of revolutions of the magnet 44 of FIG. 11 which is installed inside the rotating body 40 and rotates together with the rotating body 40.

At least four of the rotary blades 61-64 are equally spaced about the shaft 20. That is, as shown in the figure, the four rotary blades 61-64 are equally spaced at intervals of 90 degrees, and the six rotary blades 61-64 are spaced at intervals of 60 degrees and eight at equal intervals of 45 degrees.

In addition, the rotary vanes 61-64 are all formed in a recessed shape so as to receive the wind force effectively, and all of the rotary vanes 61-64 are provided so that the recessed direction is oriented in the same rotation direction about the shaft 20, Which is perpendicular to the longitudinal direction of the shaft 20, and generates a rotational force to rotate the rotary body 40 about the shaft 20. [

The rotary vanes 61-64 are fixed at positions radially extending from the rotary body 40 by the supports 51-54.

In this embodiment, the rotary vanes 61-64 are provided with a rotary vane 61-64 provided above the average height H of the rotary vanes and a rotary vane 61-64 provided below the average height H, Are arranged alternately.

The rotary blades 61-64 provided above the average height H are all the same height and the rotary blades 61-64 provided below the average height H are all made to have the same height It is most preferable because it is rotationally symmetric about the shaft 20 and can maintain up-and-down balance.

In order to arrange the rotary vanes 61-64 in such a manner that the rotary vanes 61-64 are positioned above and below the average height H, the four supports 51-54 supporting the rotary vanes 61-64 So that the upper and lower sides are alternately formed so that the positions of the rotary vanes 61-64 can be arranged as described above.

Particularly, in the case of this embodiment in which the four rotary blades 61-64 are installed at equal intervals, the upper ones 62, 64 of the four rotary blades 61-64 rotate the shaft 20, And the lower portions 61 and 63 are also paired to form rotational symmetry about the shaft 20 as a rotation center.

4 and 5, the rotary blades 61 are located below the average height H, the rotary blades 62 are above the average height H, and the rotary blades 63 Below the average height H, the rotating blades 64 are located above the average height H.

Fig. 5 is a front view of the anemometer of this embodiment seen from the wind direction side. In the vanes 61-64 of the container shape with respect to the wind direction, reference numerals 61 and 62 denote wind turbines.

Since the rotary blades 62 receiving the wind force in this state are not blocked by the rotary blades 61, the wind force can be converted into the rotary force without being disturbed by the rotary blades 61 positioned at the front.

Fig. 7 is a front view of the anemometer of this embodiment viewed from the wind direction side, and shows a state in which the rotary vane 61-64 rotates about the shaft 20 by receiving wind power.

In Fig. 7 (a), the rotating blades 61 and 62 are not interfered with each other and the wind force can be converted into rotational force. In Fig. 7 (b) And the wind force is converted into rotational force as the maximum receiving posture.

7 (c) is a further rotated state in Fig. 7 (b), in which the rotating blades 61 are rotated backward and are not disturbed by the rotating blades 64, You can get enough wind until you get back.

In FIG. 7 (d), the rotary blade of the reference numeral 61, which rotates rearward, is in a hidden state, and the rotary blade of the reference numeral 64, in which the recessed surface is completely opened,

As described above, the rotating blades located on the upper and lower sides are alternately disposed in the rotating direction around the shaft 20, so that the wind power generating rotating force can be received without being interfered with each other.

Accordingly, the anemometer of this embodiment can generate a relatively large rotational force with respect to the same wind force by sufficiently receiving the wind power as compared with the conventional anemometer, so that the rotation vane of the anemometer can rotate about the shaft 20 have. This makes it possible to measure the wind speed more precisely than in the past.

Even if the rotary blades 61-62 alternately arranged on the upper and lower sides obscure portions of the wind direction, the area obstructed by receiving the wind force is reduced compared to the prior art, The same effect can be expected.

Figs. 8 and 9 show an anemometer in which six rotary vanes 611-616 are arranged at intervals of 60 degrees.

In such an embodiment as well, the rotary vanes 611-616 may be alternately arranged above and below, and as described above, the rotary vanes receiving the wind force may receive the wind force without being disturbed by the rotary vanes rotating in front of it .

Fig. 10 shows an anemometer in which eight rotary vanes 621-628 are arranged at intervals of 45 degrees. In the case of this embodiment, the rotating blades 621-628 can also be alternately arranged on the upper and lower sides.

When four or eight rotary blades are provided, a pair of rotary blades facing each other can be arranged at the same height on the upper side or the lower side while being rotationally symmetric with respect to the shaft 20 as a center, It is possible to rotate with a stable feeling.

In the anemometer of this embodiment, the rotary body 40 has a rotationally symmetrical shape about the shaft 20, covers the upper portion of the body 10 with an interval, And an inner space 72 is formed between the inner surface and the upper portion of the body 10.

The internal space 72 is a space in which a substrate or the like of the measuring means 14 is installed, and is a space in which the inflow of foreign matter or the like should be blocked.

The minimum clearance S that minimizes the gap between the rotating body 40 and the body 10 so as to prevent foreign substances from flowing into the inner space 72 along the outer circumference of the rotating body 40 And is formed in an annular shape along the periphery. The minimum spacing S is the minimum spacing in which the rotating body 40 can rotate without interfering with the body 10.

However, in the case of such a minimum clearance portion S as well, as shown in FIG. 3, the air becomes a passage through which the air flows, and while the air is flowing into the internal space 72 by the wind, foreign substances such as rainwater or dust Respectively.

In this embodiment, a plurality of protrusions 42 are formed on the inner surface of the rotating body 40 to generate a turbulent flow in the minimum interval portion S when the rotating body 40 rotates.

11 is a perspective view showing a configuration in which protrusions 42 are formed inside the rotating body 40. As shown in Fig.

11, a plurality of projections 42 are formed on the inner space 72 side of the minimum spacing portion S, and a plurality of protrusions 42 are formed on the side of the rotation spacing portion S as in the case of the minimum spacing portion S, A plurality of projections 42 are arranged at regular intervals along the circumference of the rotating body 40 so as to form an annular trajectory as a whole.

12, the protrusion 42 rotates together with the rotating body 40 while the air gap 43 between the protrusions 42 draws air to disturb the surrounding air, The turbulence A is generated in the minimum interval S. The turbulent flow A formed in the minimum interval portion S serves as an air curtain and interferes with the inflow of air toward the inner space 72 from the outside.

Particularly, when the wind force is strong, the flow force to flow air into the internal space 72 through the minimum interval portion S becomes large. In this case, however, the rotating blades also receive strong wind force, And the turbulence A is more strongly generated in the minimum interval portion S, so that the construction of the present embodiment can generate a strong blocking force corresponding to inflow of air due to strong wind.

Accordingly, the inflow of rainwater or foreign matter into the internal space 72 is blocked, thereby causing a trouble in the electronic device such as a sensor, and a problem that the foreign matter sticks between the shaft 20 and the rotating body 40, Can be solved.

By forming the protrusions 42 on the side of the inner space 72 of the minimum space S, it is possible to generate turbulence in the minimum space S, S), it is possible to maintain only the minimum interval uniformly. When the protrusion 42 is formed at the outermost side of the minimum space S, the gap 430 between the protrusions 42 can serve as a passage for foreign matter or rainwater inflow.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

10; A body 14; Measuring means
20; Shaft 23; Annular support portion
30; Bearing 31; Radial bearings
32; A thrust bearing 40; Rotating body
42; A projection 43; aperture
44; Magnets 61-64, 611-616, 621-628; Rotary wing
72; Internal space S; Minimum spacing
A; turbulence

Claims (6)

A body 10,
A shaft 20 coupled to the body 10 and installed vertically,
A rotating body 40 coupled to the shaft 20 through a bearing 30 to rotate about the shaft 20,
And is positioned outside the rotating body 40 and coupled to the rotating body 40 by the supporting body 51-54 to receive the wind in the direction perpendicular to the longitudinal direction of the shaft 20, (61-64) of a hollow container shape for rotating the rotor
And measurement means (14) coupled to the body (10) for measuring the number of revolutions of the rotating body (40)
The rotary blades 61-64 are provided so that four or more even numbered teeth are equally spaced around the shaft 20 so that all of the rotary blades 61-64 are oriented in the same rotation direction about the shaft 20,
The rotary blades 61-64 are arranged alternately with the rotary blades 61-64 provided above the average height H of the rotary blades and the rotary blades 61-64 provided below the average height,
The rotating body 40 is rotationally symmetrical about the shaft 20 and covers the upper portion of the body 10 with a gap therebetween,
The gap between the rotating body 40 and the body 10 is minimized along the outer circumference of the inner space 72 formed between the inner surface of the rotating body 40 and the upper portion of the body 10 The minimum spacing portion S is formed in an annular shape,
Wherein a plurality of protrusions (42) for generating a turbulent flow in the minimum clearance portion (S) are formed on the inner surface of the rotating body (40) along the circumference when the rotating body (40) The method according to claim 1,
The rotating blades 61-64 provided above the average height are all of the same height,
The rotating blades 61-64 provided below the average height are all of the same height,
The bearing 30 includes a radial bearing 31 and a thrust bearing 32 provided between the shaft 20 and the rotating body 40,
The shaft 20 is integrally formed with the annular bearing portion 23 below the thrust bearing 32 so as to support the thrust bearing 32, Characterized in that the shaft (20) supports the vertical load of the rotating body (40) A body 10,
A shaft 20 vertically erected at the upper end of the body 10,
A bearing 30 mounted on the shaft 20,
A rotating body 40 coupled to the bearing 30 and freely rotatable about the shaft 20,
Four supporting members 51-54 extending at an interval of 90 degrees from the rotating body 40 and extending outwardly around the shaft 20,
And is rotatably connected to the end portions of the four supports 51-54 so as to receive the wind in a direction perpendicular to the longitudinal direction of the shaft 20, Four rotary blades 61-64 oriented in the same rotational direction about the shaft 20,
And measuring means (14) coupled to the body (10) for measuring the number of revolutions of the rotating body (40)
The four supports 51-54 extend radially outward and are alternately bent upward and downward so that the four rotary blades 61-64 are alternately located on the upper side and the lower side, Disposed,
The rotating body 40 is rotationally symmetrical about the shaft 20 and covers the upper portion of the body 10 with a gap therebetween,
The gap between the rotating body 40 and the body 10 is minimized along the outer circumference of the inner space 72 formed between the inner surface of the rotating body 40 and the upper portion of the body 10 The minimum spacing portion S is formed in an annular shape,
Wherein a plurality of protrusions (42) for generating a turbulent flow in the minimum clearance portion (S) are formed on the inner surface of the rotating body (40) along the circumference when the rotating body (40) The method of claim 3,
The upper one of the four rotary blades 61-64 is a pair which is rotationally symmetric about the shaft 20 as a rotation center,
And a pair of the lower portions are rotationally symmetric with respect to the shaft 20 as a rotation center,
The bearing 30 includes a radial bearing 31 and a thrust bearing 32 provided between the shaft 20 and the rotating body 40,
The shaft 20 is integrally formed with the annular bearing portion 23 below the thrust bearing 32 so as to support the thrust bearing 32, Characterized in that the shaft (20) supports the vertical load of the rotating body (40) 5. The method according to any one of claims 1 to 4,
The projections (42)
A plurality of annular grooves are formed in the inner space of the minimum spacing part S on the inner surface of the rotating body 40 so as to form an annular trajectory along the circumference of the rotating body 40 An anemometer delete

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