KR20120001882U - Device for controlling ventilation direction - Google Patents

Abstract

Disclosed is a device for controlling a blowing direction. The disclosed blowing direction adjusting device is a drive motor installed in the main body to provide power to the drive gear coupled to the shaft, a first drive link unit coupled to one side of the drive gear to provide rotational force, coupled to the other side of the drive gear, the first The first blower wing and the main body consisting of a second drive link unit for providing a rotational force in the opposite direction to the drive link unit, at least one group installed on one side of the main body in the discharge port of the main body, and rotated by the first drive link unit It is installed on the other side with respect to the center in the discharge port of the, characterized in that it comprises a second blowing blade made of one or more groups rotated in a symmetrical direction with the first blowing blade by the second drive link.

Description

Blowing direction control device {DEVICE FOR CONTROLLING VENTILATION DIRECTION}

The present invention relates to a blowing direction adjusting device, and more specifically, the blowing direction to widen the blowing area because the blowing direction of the first and second blowing blades are different from each other by disposing asymmetric gear structures around the driving motor. It relates to a control device.

In general, an air conditioner is an apparatus used to properly warm or cool air in a building or a home, and includes an air conditioner and a heater.

Among the air conditioners, air conditioners are mainly used for the wall type, the stand type and the ceiling type.The wall type is small and often installed in the windows, so it is used for the room or the small living room. It is widely used in living rooms and living spaces.

1 is a view showing a conventional stand-type air conditioner.

Conventional stand-type air conditioner is provided in front of the air conditioner main body 2, the air conditioner main body 2, the discharge port (4) for discharging the air sucked in the inlet (1) to the cold heat exchanged in the indoor heat exchanger and cooled; And left and right blowing wings 6 for adjusting the left and right directions of the cold air blown by the discharge port 4; And a vertical blower blade 8 installed at the front side of the left and right blower blades to adjust a vertical direction of the cold air blown by the discharge port 4.

The above technical configuration is a background art for helping understanding of the present invention, and does not mean a conventional technology well known in the art.

By the way, in the case of the conventional stand-type air conditioner, there is a problem that the inconvenience in use because the air blow direction to be adjusted by manually operating the left and right blowing wings.

 In addition, in the conventional stand-type air conditioner, since both the left and right blowing blades rotate to the left or to the right at the same time there was a problem that the area to be blown very narrow.

Thus, there is a need for improvement.

The present invention is created by the necessity as described above, by arranging the asymmetric gear structure on both sides around the drive motor to change the blowing direction of the first and second blowing blades different from the blowing direction adjusting device for widening the blowing area. The purpose is to provide.

In order to achieve the above object, a blowing direction adjusting apparatus according to an embodiment of the present invention, the drive motor is installed in the main body to provide power to the shaft coupled drive gear; A first drive link unit coupled to one side of the drive gear to provide a rotational force; A second driving link unit coupled to the other side of the driving gear and providing rotational force in a direction opposite to the first driving link unit; A first blowing vane installed at one side of the discharge port of the main body with respect to a center and formed of at least one group rotated by the first driving link unit; And a second blower vane disposed on the other side of the discharge port of the main body with respect to the center and formed of at least one group rotated in a symmetrical direction with the first blower vane by the second drive link.

The first driving link unit may include: a first driven gear coupled to the first driving shaft to be engaged with one side of the driving gear; A first rotating link having one end coupled to the first driving shaft to rotate the other end; And a first linear link operating linearly by a first operating shaft inserted into the first installation hole formed at the other end of the first rotating link and rotating the first blowing blade.

In addition, the first installation hole is a long hole formed in the longitudinal direction at the other end of the first rotary link to compensate for the rotational distance during the rotation of the first rotary link, the lower end of the rear of the first blower blade in the first linear link The first insertion hole is formed is inserted into the first rotary shaft is formed in the first blowing blade is characterized by rotating the first blowing blade around the first hinge shaft formed on the front lower end.

The second link driving unit may include an intermediate gear axially coupled to be engaged with the other side of the driving gear; A second driven gear meshed with the intermediate gear and coupled to a second drive shaft to rotate in a direction opposite to the first driven gear; A first rotating link having one end coupled to the second driving shaft to rotate the other end; And a second linear link operating linearly by a second operating shaft inserted into the second installation hole formed at the other end of the second pivoting link, and rotating the second blowing blade.

In addition, the second installation hole is a long hole formed in the longitudinal direction at the other end of the second pivoting link to compensate for the rotational distance during the rotation of the second pivoting link, the lower end of the rear of the second blower blade in the second straight link The second insertion hole is formed is inserted into the second rotary shaft formed in the rotational movement of the second blowing blades around the second hinge shaft formed on the front lower end of the second blowing blades.

In addition, the first blowing blades and the second blowing blades are arranged in the same number symmetrically around the center of the discharge port, the first blowing blades and the second blowing blades are installed perpendicular to the discharge port left and right It characterized in that the left and right blowing blades to adjust the blowing direction in the direction.

As described above, the blowing direction adjusting device according to the present invention, by arranging the asymmetric gear structure on both sides around the drive motor to change the blowing direction of the first and second blowing blades different from each other, so that the blowing is performed using a simple gear structure. It has the effect of significantly widening the area.

1 is a perspective view showing a conventional stand type air conditioner.
Figure 2 is an exploded perspective view of the blowing direction adjusting apparatus according to an embodiment of the present invention.
Figure 3 is an assembled perspective view of the blowing direction adjusting apparatus according to an embodiment of the present invention.
Figure 4 is a cross-sectional view from the bottom when narrowing the blowing direction of the blowing direction control apparatus according to an embodiment of the present invention.
Figure 5 is a cross-sectional view from the bottom when extending the blowing direction of the blowing direction control apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a blowing direction adjusting apparatus according to a preferred embodiment of the present invention.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

Figure 2 is an exploded perspective view of the blowing direction adjusting apparatus according to an embodiment of the present invention. Figure 3 is an assembled perspective view of the blowing direction adjusting apparatus according to an embodiment of the present invention, Figure 4 is an embodiment of the present invention Cross-sectional view seen from the bottom when the blowing direction of the apparatus for adjusting the blowing direction according to Figure 5 is a cross-sectional view viewed from the bottom when the blowing direction of the blowing direction control apparatus according to an embodiment of the present invention.

2 to 5, the blowing direction adjusting apparatus according to an embodiment of the present invention, the drive motor 10, the first driving link unit 20, the second driving link unit 40, the first blowing It comprises a wing 60 and the second blowing wing 70.

The drive motor 10 is installed in the main body 2 to provide power to the drive gear 12 coupled to the shaft. The main body 2 is a main body applied to a stand type air conditioner or a device for blowing cold air or warm air.

The first drive link unit 20 is coupled to one side of the drive gear 12 to provide rotational force.

The first driving link unit 20 includes a first driven gear 22, a second rotating link 26, and a first straight link 30.

The first driven gear 22 is coupled to the first drive shaft 24 to be engaged with one side of the drive gear 12. The first drive shaft 24 is pivotally coupled to the body 2 in a rotatable manner.

One end of the first rotating link 26 is coupled to the first driving shaft 24, and the other end thereof rotates according to the rotation of the first driving shaft 24.

The first linear link 30 is linearly operated by the first operating shaft 32 inserted into the first installation hole 28 formed at the other end of the first rotational link 26, and the first blowing blade 60 is provided. Rotate

The first installation hole 28 is a long hole formed in the longitudinal direction at the other end of the first rotation link 26 to compensate for the rotation distance when the first rotation link 26 rotates.

The first linear link 30 is formed with a first insertion hole 34 into which the first rotary shaft 64 formed at the rear lower end of the first blower blade 60 is inserted, thereby lowering the front lower end of the first blower blade 60. The first blowing blades 60 are rotated about the first hinge shaft 62 formed at the center.

The first insertion hole 34 of the first linear link 30 is preferably formed by the number of the first blowing blades 60 and is formed at equal intervals.

The second drive link unit 40 is coupled to the other side of the drive gear 12 and provides rotational force in a direction opposite to the first drive link unit 20.

The second driving link unit 40 includes an intermediate gear 41, a second driven gear 42, a second rotating link 46, and a second straight link 50.

The intermediate gear 41 is pivotally coupled in the main body 2 so as to be engaged with the other side of the drive gear 12.

The second driven gear 42 is engaged with the intermediate gear 41 and is coupled to the second drive shaft 44 to rotate in the opposite direction to the first driven gear 22. The second drive shaft 44 is pivotally coupled to the body 2 in a rotatable manner.

One end of the second rotating link 46 is coupled to the second driving shaft 44, and the other end of the second rotating link 46 rotates according to the rotation of the second driving shaft 44.

The second linear link 50 is linearly operated by the second operation shaft 52 inserted into the second installation hole 48 formed at the other end of the second rotation link 46, the second blowing blade 70 Rotate

The second installation hole 48 is a long hole formed in the longitudinal direction at the other end of the second rotation link 46 to compensate for the rotation distance when the second rotation link 46 rotates.

The second linear link 50 is formed with a second insertion hole 54 into which the second rotary shaft 74 formed at the rear lower end of the second blower blade 70 is inserted, and thus the front lower end of the second blower blade 70. The second blower blade 70 is rotated around the second hinge shaft 72 formed at the center.

The second insertion hole 54 of the second straight link 50 is preferably formed by the number of the second blowing blades 70 and is formed at equal intervals.

The first blowing blades 60 are installed on one side of the discharge port 4 of the main body 2 with respect to the center thereof, and include one or more groups that are rotated by the first driving link unit 60.

The second blowing blade 70 is installed on the other side with respect to the center in the discharge port 4 of the main body 2, and rotates in a symmetrical direction with the first blowing blade 70 by the second driving link 70. It consists of the above group.

The same number of first blower blades 60 and second blower blades 70 are arranged symmetrically about the center of the discharge port 4.

The first blowing blades 60 and the second blowing blades 70 are preferably vertically installed at the discharge port 4 and are left and right blowing blades 6 for controlling the blowing direction in the left and right directions. Of course, the first blowing blades 60 and the second blowing blades 70 may be horizontally installed in the discharge port 4 and the left and right blowing blades 8 to adjust the blowing direction in the vertical direction.

In addition, the first blowing blades 60 and the second blowing blades 70 may be installed to collect the blowing direction or open the blowing direction by applying to various blowers as well as various types of air conditioners.

Or less, on the basis of the accompanying drawings to look at the action and effect of the blowing direction adjusting apparatus according to an embodiment of the present invention.

As shown in FIG. 4, first, a state of closing the first blowing blades 60 and the second blowing blades 70 will be described.

When the drive motor 10 is rotated counterclockwise, the first driven gear 22 of the first drive link portion 20 engaged with the left side of the drive gear 12 is clockwise around the first drive shaft 24. Rotate to

In addition, the first rotational link 26 integrally coupled to the first driving shaft 24 also rotates clockwise to rotate the first operation shaft 32 inserted into the first installation hole 28 to the left.

Then, the first linear link 30 is moved to the left by the left movement of the first operating shaft 32, the first rotary shaft 64 is coupled to the first insertion hole 34 of the first linear link (30). ) Is pushed to the left side so that the first blowing blade 60 rotates clockwise around the first hinge shaft 62 fixed to the main body 2, and the blowing direction is determined to the right.

Then, the intermediate gear 41 of the second drive link portion 40 meshed with the right side of the drive gear 12 rotates clockwise about the axis.

The second driven gear 42 meshed with the right side of the intermediate gear 41 rotates in the counterclockwise direction with respect to the second drive shaft 44.

In addition, the second rotational link 46 integrally coupled to the second driving shaft 44 also rotates counterclockwise to rotate the second operation shaft 52 inserted into the second installation hole 48 to the right.

Then, the second linear link 50 is moved to the right by the right movement of the second operating shaft 52, the second rotary shaft 74 is coupled to the second insertion hole 54 of the second linear link 50 ) Is pushed to the right so that the second blowing blade 70 rotates counterclockwise around the second hinge shaft 72 fixed to the main body 2, and the blowing direction is determined to the left.

As such, the first blowing blade group 60 and the second blowing blade group 70 are bunched when viewed from the front with respect to the center portion, so that the blowing direction is collected at the center.

Meanwhile, as shown in FIG. 5, first, a state in which the first blowing blades 60 and the second blowing blades 70 are opened will be described.

When the driving motor 10 is rotated in the clockwise direction, the first driven gear 22 of the first driving link unit 20 engaged with the left side of the driving gear 12 is counterclockwise around the first driving shaft 24. Rotate to

In addition, the first rotating link 26 integrally coupled to the first driving shaft 24 also rotates counterclockwise to rotate the first operating shaft 32 inserted into the first installation hole 28 to the right.

In addition, the first linear link 30 is moved to the right by the right movement of the first operating shaft 32, and the first rotary shaft 64 is axially coupled to the first insertion hole 34 of the first linear link 30. ) Is pushed to the right, so that the first blowing blade 60 rotates counterclockwise about the first hinge shaft 62 fixed to the main body 2, and the blowing direction is determined to the left.

Then, the intermediate gear 41 of the second drive link portion 40 meshed with the right side of the drive gear 12 rotates in the counterclockwise direction about the axis.

Then, the second driven gear 42 meshed with the right side of the intermediate gear 41 rotates clockwise around the second drive shaft 44.

In addition, the second rotational link 46 integrally coupled to the second driving shaft 44 also rotates clockwise to rotate the second operating shaft 52 inserted into the second installation hole 48 to the left.

Then, the second linear link 50 is moved to the left by the left movement of the second operating shaft 52, the second rotary shaft 74 is coupled to the second insertion hole 54 of the second linear link 50 ) To the left, the second blowing blade 70 is rotated clockwise around the second hinge shaft 72 fixed to the main body 2 to determine the blowing direction to the right.

As such, the first blowing blade group 60 and the second blowing blade group 70 open to both sides when viewed from the front with respect to the center, so that the blowing direction covers not only the central direction but also the wide left and right areas based on the center. It is blown.

Accordingly, the present invention arranges the asymmetric gear structures on both sides of the driving motor 10 so that the blowing directions of the first and second blowing blades are different from each other, so that a wider area can be blown using a simple gear structure. Has an effect.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. Will understand.

Therefore, the true technical protection scope of the present invention should be determined by the utility model registration claims below.

2: main body 10: drive motor
12: drive gear 20: first drive link portion
22: first driven gear 26: first driven link
30: first linear link 40: second drive link unit
42: intermediate gear 42: second driven gear
50: second straight link 60: first blowing wing
64: first rotating shaft 70: second blowing wing

Claims (6)

A drive motor installed in the main body to provide power to the drive gear coupled to the shaft;
A first drive link unit coupled to one side of the drive gear to provide a rotational force;
A second driving link unit coupled to the other side of the driving gear and providing rotational force in a direction opposite to the first driving link unit;
A first blowing vane installed at one side of the discharge port of the main body with respect to a center and formed of at least one group rotated by the first driving link unit; And
Blowing direction characterized in that it is provided on the other side with respect to the center in the discharge port of the main body, and the second blowing wing made of one or more groups rotated in the symmetrical direction with the first blowing wing by the second driving link. Regulator.
The method of claim 1, wherein the first drive link unit
A first driven gear coupled to a first drive shaft to be engaged with one side of the drive gear;
A first rotating link having one end coupled to the first driving shaft to rotate the other end; And
And a first linear link linearly operated by a first operating shaft inserted into a first installation hole formed at the other end of the first pivot link and rotating the first blower blade.
The method of claim 2,
The first installation hole is a long hole formed in the longitudinal direction at the other end of the first rotating link to compensate for the rotational distance when the first rotating link,
The first linear link is formed with a first insertion hole into which the first rotary shaft formed at the rear lower end of the first blower blade is inserted, thereby providing a first blower blade around the first hinge shaft formed at the front lower end of the first blower blade. Blowing direction control device characterized in that the rotating.
The method of claim 1, wherein the second link driving unit
An intermediate gear axially coupled to the other side of the drive gear;
A second driven gear meshed with the intermediate gear and coupled to a second drive shaft to rotate in a direction opposite to the first driven gear;
A first rotating link having one end coupled to the second driving shaft to rotate the other end; And
And a second linear link for linearly operating by a second operating shaft inserted into a second installation hole formed at the other end of the second pivoting link and for rotating the second blowing vane.
The method of claim 4, wherein
The second installation hole is a long hole formed in the longitudinal direction at the other end of the second rotary link to compensate for the rotation distance when the second rotary link,
The second straight link is formed with a second insertion hole into which the second rotary shaft formed at the rear lower end of the second blower blade is inserted, thereby providing a second blower blade around the second hinge shaft formed at the front lower end of the second blower blade. Blowing direction control device characterized in that the rotating.
The method of claim 1,
The first blowing blades and the second blowing blades are arranged in the same number symmetrically around the center of the discharge port,
The first blowing blade and the second blowing blade is installed vertically to the discharge port blowing direction control device, characterized in that the left and right blowing blades to adjust the blowing direction in the left and right directions.

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