KR20140022609A - Diffuser having function of controlling direction of wind - Google Patents

Abstract

The present invention relates to an air conditioning diffuser having an automatic wind direction control function. An air conditioning diffuser of the present invention comprises: a casing connected to an end of a feeding duct; a frame which is fixed to the inside of the casing, and has a vertical guide hole; a rod member which is able to lift in a state of being supported to the guide hole, and has an upper part and a lower part located in the upper part and the lower part of the frame; a wind direction control part which is combined to the lower part of the rod member, and is elevated with a rod; a supporting unit comprised in the upper part of the rod member; a shape memory spring which reacts to the temperature of air supplied through the feeding duct, and supports the supporting unit upward elastically by being installed between the frame and the supporting unit; and a coil spring which is located between the frame and the wind direction control part, and supports the lower part of the rod member elastically. Accordingly, the air conditioning diffuser having an automatic wind direction control function uses the coil spring and the shape memory spring serially arranged for elevation motion of the wind direction control part and thus has a simple structure and light weight. Because the diffuser of the present invention does not use electricity, an installation work like electric wiring is not necessary. The diffuser can perform the highest performance under any condition because the position of the wind direction control part is optimally controlled by the shape memory spring in real-time.

Description

Diffuser having function of controlling direction of wind}

The present invention relates to an air conditioner diffuser having an automatic wind direction control function.

Recently built apartments, office buildings, or residential complexes maintain very high airtightness to minimize the consumption of heating and cooling energy, and most of them employ centrally controlled air conditioning to create the most comfortable environment. The air conditioning apparatus used for the control of the central air control functions to filter the fresh air outside the building and supply it to the room, and suck out the polluted air in the room and discharge it to the outside.

There are a wide variety of air conditioners described above, but includes an air supply duct for supplying air to the room and an exhaust duct for discharging the indoor air to the outside in common. The air supply duct and the exhaust duct are disposed on the ceiling of the room, and supply air to every corner of the indoor space or intake polluted air and discharge it to the outside.

Ends of the air supply duct and the air exhaust duct are equipped with diffusers for more effectively supplying and discharging air. The diffuser installed in the air supply duct serves to spread the air passing through the air supply duct to a wider range of the indoor space. In addition, the diffuser fixed to the exhaust duct quickly induces the contaminated air in the room to the exhaust duct, thereby allowing the exhaust to be smoothly discharged.

On the other hand, the most important thing in the above-mentioned air supply diffuser is to spread air more efficiently in the indoor space. For example, when supplying cold air in the summer, cold air does not descend directly from the diffuser, but rather spreads as much as possible along the ceiling and descends.When supplying hot air in the winter, the hot air is first lowered to induce convective heating. It is.

To this end, various wind direction control devices may be installed inside the diffuser to control the wind direction of the supply air.

1 is a partial cross-sectional view showing a conventional diffuser 11 having a wind direction control function.

As shown in the drawing, the conventional diffuser 11 having a wind direction control function includes a casing 13 installed on the ceiling while being connected to an end of an air supply duct (not shown), and an air flow provided by the casing 13. It includes a wind direction control body 15 that is installed to be able to move up and down in the furnace (13a), and lifting means for raising and lowering the wind direction control body (15).

The elevating means rotates the rack gear 17 which is fixed vertically to the upper part of the wind direction regulator 15, the pinion gear 19 meshing with the rack gear 17, and the pinion gear 19. It includes a motor 21 to make. The drive shaft 23 of the motor 21 is fixed to the pinion gear 19 to transfer the rotational torque of the motor to the rack gear 17. Reference numeral 25 denotes a support bracket for supporting the motor 21.

In the diffuser 11 having the above configuration, in order to adjust the wind direction of the air supplied through the diffuser 11, the height of the wind direction controller 15 may be adjusted. According to the height of the wind direction regulator 15, the flow pattern of air flowing downward is changed.

For example, when the wind direction regulator 15 rises, the air flowing into the diffuser 11 hits the wind direction regulator 15 and then hits the inner wall surface of the casing 13 to move mostly downward, and the wind direction regulator 15 When the air is lowered, the air strikes the wind direction regulator 15 and then spreads in the radial direction.

The motor 21 is used to adjust the height of the wind direction regulator 15. That is, by sending an electric signal to the motor 21 to rotate the drive shaft 23 in one direction or the opposite direction to raise and lower the wind direction regulator (15).

In winter, the air is dropped downward by raising the wind direction regulator 15 through the drive shaft 23, and in summer, the wind direction regulator 15 is lowered by rotating the drive shaft 23 in the opposite direction to diffuse the diffuser. It is to allow the cold air to escape widely.

However, the conventional diffuser 11 has a structural disadvantage of using a motor and electricity to elevate the wind direction regulator 15. This problem not only raises the cost of the diffuser but also causes various problems in installation and maintenance.

For example, since one motor is required for one diffuser 11, the unit cost of the diffuser is very high, and installation cost is very high because electrical wiring must be separately set inside the ceiling to install the diffuser. In particular, if the use time is long or humid, there is a danger of fire due to short circuit or short circuit.

In addition, the wind direction controller 15 does not move automatically according to temperature, but moves only when the motor 21 is driven. Therefore, if the motor 21 cannot be driven or the motor does not operate due to a failure, It becomes impossible to adjust.

In addition, even if the motor 21 can be driven, positioning the wind direction regulator 15 at the optimum point requires some skilled experience, so without a skilled manager, the function of the diffuser can be properly utilized. There will be no. For example, cold air in summer and warm air do not spread evenly in winter, the cooling and heating performance is significantly reduced.

The present invention has been created to solve the above problems, and because the structure uses the action of the shape memory spring and the coil spring arranged in series for the lifting motion of the wind direction control body, the structure is simple and lightweight, and in particular does not use electricity, etc. In addition to the need for installation work, it is an object of the present invention to provide an air conditioner diffuser having an automatic wind direction control function that can show the best performance under any conditions because the position of the wind direction control body is optimally controlled in real time by the shape memory spring.

Air-conditioning diffuser having an automatic wind direction control function of the present invention for achieving the above object is to pass through the air supplied from the outside through the air supply duct to diffuse and discharge into the room, connected to the end of the air supply duct and into A casing for passing air; A frame fixed to the inside of the casing with a guide hole extending vertically; A hollow rod member penetrating the guide hole and being capable of lifting in a state supported by the guide hole, extending in the longitudinal direction, and having upper and lower ends positioned at upper and lower portions of the frame; A wind direction adjuster coupled to the lower end of the rod member to adjust the flow direction of the air passing through the casing by lifting up and down with the rod; A support means provided at an upper end of the rod member and capable of adjusting a position with respect to the frame by elevating with the rod member; Responsive to the temperature of the air supplied through the air supply duct, the shape memory spring for elastically supporting the support means in a state installed between the frame and the support means; Located between the frame and the wind direction control member characterized in that it comprises a coil spring for elastically supporting the rod member to the bottom.

In addition, the rod member is a hollow pipe-like member having a rectangular cross section, the support means, the screw screwed to the upper end of the rod member, the adjustment screw for adjusting the distance to the frame according to the degree of screwing the rod member It includes, the shape memory spring, characterized in that for supporting the adjustment screw upward in the state sandwiched between the head portion of the adjustment screw and the frame while the rod member is wrapped.

In addition, a male screw rod screwed to the lower end of the rod member is fixed to the upper center of the wind direction regulator, and the coil spring is sandwiched between the frame and the wind direction regulator with the rod member wrapped. do.

In addition, the lower end of the rod member, characterized in that the support body for supporting the wind direction control body to the rod member, if necessary to separate the wind direction control body from the rod member.

In addition, the regulator support; A male screw rod screwed to the lower end of the rod member, and fixed to the lower portion of the male screw rod, one end of which is pivotally connected to an upper surface of one side of the wind direction regulator, and the other end of the hinge based on the male screw rod. Located on the opposite side is characterized in that it comprises a resilient holder for resiliently supporting the wind direction regulator.

The air conditioner diffuser having the automatic wind direction control function of the present invention made as described above is simple in structure, light in weight, and in particular, does not use electricity because the shape memory springs and the coil springs are arranged in series for the lifting motion of the wind direction control body. Therefore, installation work such as electric wiring is not necessary, and since the position of the wind direction control body is optimally controlled in real time by the shape memory spring, it can exhibit the best performance under any conditions.

1 is a partial cross-sectional view schematically showing a conventional air conditioner diffuser.
Figure 2 is a perspective view of the air conditioner diffuser having an automatic wind direction control function according to an embodiment of the present invention.
3 is a partially cutaway exploded perspective view of the diffuser shown in FIG. 2.
4 and 5 are cross-sectional views for explaining the operation of the diffuser shown in FIG.
6 is a partial cross-sectional view showing another example of the air conditioner diffuser having an automatic wind direction control function according to an embodiment of the present invention.
7 is a perspective view showing the wind direction control body shown in FIG. 6 separately.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view of the air conditioner diffuser having an automatic wind direction control function according to an embodiment of the present invention, Figure 3 is a partially cutaway exploded perspective view of the diffuser shown in FIG.

As shown, the air conditioner diffuser 31 having an automatic wind direction control function according to the present embodiment is fixed to an end of an intake duct (not shown), and a casing 33 for passing air therein, and the casing. Frame 35 having a rectangular guide hole 35a in the central axis of the casing 33 and fixed to the inside of the 33, and a rod member 37 vertically extending through the guide hole 35a; And an adjustment screw 43 and a support plate 41 positioned at an upper end of the rod member 37, a shape memory spring 39 provided between the support plate 41 and the frame 35, and the rod member. The wind direction controller 51 is fixed to the lower end of the 37 and has a configuration including a coil spring 49 located between the wind direction controller 51 and the frame 35.

The shape memory spring 39 and the coil spring 49 are compression coil type springs.

First, the casing 33 is formed of a metal plate and has a substantially cylindrical shape and is extended downward. In this embodiment, the casing 33 takes the form of a cylinder, but of course it can also be applied in a rectangular type.

The frame 35 serves to support the wind direction control body 51 to be lifted and lowered through the rod member 37 while being fixed to the inside of the casing 33. The hole 35a is provided. The frame 35 is fabricated by welding four belt-shaped metal plates having a predetermined width in the width direction and welded to each other and welded to the inner wall of the casing 33.

The guide hole 35a is a rectangular passage extending in the vertical direction in the drawing and passes the rod member 37 therein.

The rod member 37 is a hollow rectangular pipe having a predetermined cross-section in the longitudinal direction, and is fitted into the guide hole 35a and can be elevated in an interview state with the inner wall surface of the guide hole 35a. Thus, by forming the guide hole 35a and the rod member 37 in a square shape, there is no fear that the rod member 37 will return to an axial direction. That is, even if the vibration is applied from the outside or other forces are exerted, it does not rotate, but only rises or falls.

Further, female screw portions 37a are provided at the upper and lower ends of the rod member 37. The female screw portion 37a is a portion to which the threaded portion 43b and the male screw rod 51a of the adjusting screw 43 are coupled, respectively. The threaded portion 43b and the male threaded rod 51a can be positioned up and down through axial rotation while being screwed to the female threaded portion 37a.

The adjusting screw 43 is screwed to the upper end of the rod member 37 in the state of being fitted into the guide hole 35a. The adjusting screw 43 is axially rotatable in a state that is screwed to the female screw portion (37a) formed on the top of the rod member 37. As the adjusting screw 43 is axially rotated, the separation distance of the adjusting screw 43 with respect to the frame 35 is adjusted as described above.

In addition, the support plate 41 is located under the head portion 43a of the adjusting screw 43. The support plate 41 is a washer-shaped member having a predetermined thickness, and is located between the head portion 43a and the shape memory spring 39, and transmits the elastic force of the shape memory spring 39 to the adjustment screw 43. .

A spring receiving 45 is positioned between the lower end of the shape memory spring 39 and the frame 35. The spring bearing 45 is a disk-shaped member having a predetermined thickness and has a rectangular through hole 45a for passing the rod member 37. The spring bearing 45 supports the shape memory spring 39 to the upper part of the frame 35.

On the other hand, the shape memory spring 39 is a coiled spring made of a shape memory alloy, it is sandwiched between the support plate 41 and the spring support 45 in a state of wrapping the rod member 37. The shape memory spring 39 responds to the temperature of the air introduced through the intake duct (by interaction with the coil spring 49) and causes the wind direction regulator 51 to rise or fall.

The shape memory spring 39 changes in elastic modulus in response to the temperature of air passing through the shape memory spring 39. In other words, as the temperature increases, the intrinsic elastic force increases. In particular, the elastic modulus of the shape memory spring 39 is greater than the elastic modulus of the coil spring 49 in an environment higher than the set temperature (determined at the time of manufacturing the shape memory spring), the coil spring 49 in an environment lower than the set temperature. Is less than

Therefore, for example, when air having a temperature lower than 20 ° C. passes through the casing 33, the shape memory spring 39 has a smaller elastic force than the coil coil 49 at the lower side and is contracted by the coil spring to contract. When the temperature is higher than 20 ℃, the intrinsic elastic force of the shape memory spring 39 gradually increases, and has a larger elastic modulus than the coil spring 49 to expand.

The wind direction regulator 51 descends when the shape memory spring 39 contracts and rises when it expands. The set temperature 20 ℃ is an example temperature, the set temperature is of course changed when manufacturing the diffuser.

The wind direction regulator 51 has a male threaded rod 51a at the center of the upper surface as a member whose upper and lower surfaces are curved and convexly curved. The male threaded rod (51a) is fixed to the wind direction control body 51 through the nut (51b).

The male screw rod 51a is screwed to the female screw portion 37a formed at the lower end of the rod member 37. As the male threaded rod 51a is axially rotated, the vertical position of the male threaded rod 51a with respect to the female threaded portion 37a can be adjusted. That is, by rotating the wind direction regulator 51 clockwise or counterclockwise, the relative position of the wind direction regulator 51 relative to the rod member 37 can be finely adjusted.

In addition, a spring bearing 47 is provided between the frame 35 and the coil spring 49. The spring bearing 47 is a washer-shaped member having a rectangular through hole 47a, and supports the upper end of the coil spring 49 at the lower portion of the frame 35 while passing through the rod member 37.

The coil spring 49 is a general compression coil type spring having a constant elastic modulus, and is located between the spring receiver 47 and the wind direction control body 51 while wrapping the rod member 37. The coil spring 49 elastically supports the wind direction regulator 51 in a state in which the coil spring 49 is disposed in series with the shape memory spring 39.

The coil spring 49 is compressed by increasing the air supply temperature to increase the elastic force of the shape memory spring 39, and expands when the air supply temperature is lowered so that the elastic force of the shape memory spring 39 becomes smaller than the coil spring.

4 and 5 are cross-sectional views for explaining the operation of the diffuser 31 shown in FIG.

4 is a view when the cold air is supplied to the summer season.

Referring to FIG. 4, it can be seen that the cold air supplied through the air supply duct passes through the air flow path 33a of the casing 33 and strikes the upper surface of the wind direction regulator 51 and almost spreads in the radial direction. The cold air spreads in the radial direction in this way because the wind direction regulator 51 is lowered by that much.

The reason why the wind direction regulator 51 moves downward is that the coil spring 49 expands by overcoming the elastic force of the shape memory spring 39. As described above, when the ambient air temperature is lower than or equal to the set temperature, since the elastic modulus of the shape memory spring 39 is smaller than the elastic modulus of the coil spring 49, the coil spring 49 is controlled.

In any case, as the shape memory spring 39 contracts and the coil spring 39 expands, the support plate 41 descends to the frame 35 side, and at this time, to the threaded portion 43b of the adjusting screw 43. The engaging rod member 37 is also lowered together. When the rod member 37 descends, the wind direction control body 51 fixed thereto also descends.

When the wind direction regulator 51 is lowered as described above, the gap between the edge of the wind direction regulator 51 and the casing 33 is widened, so that the air hit by the wind direction regulator 51 does not hit the casing 33 again. Instead, it is guided to the curved surface of the upper surface of the wind direction regulator 51 and is spread out as it is in the radial direction.

5 is a view of supplying warm air in winter.

Referring to FIG. 5, it can be seen that the wind direction regulator 51 rises and enters the casing 33. The reason why the wind direction regulator 51 rises in this way is that the shape memory spring 39 responds to the temperature of the warm air. That is, as described above, since the elastic force of the shape memory spring 39 becomes larger than the elastic force of the coil spring 49 when the ambient temperature is higher than the set temperature, the coil spring 49 is dominated by the shape memory spring 39 This is because the coil spring 49 is compressed and the shape memory spring 39 expands.

When the wind direction regulator 51 rises through the above process, the gap between the edge of the wind direction regulator 51 and the casing 33 is narrowed. As the gap is narrowed as described above, the air hit by the wind direction regulator 51 hits the inner wall of the casing 33 again. That is, most of the air is discharged downward along the direction in which the inner wall surface of the casing 33 is guided while being hit by the inner wall surface of the casing 33.

As described above, the warm air discharged to the lower part ascends and rises by convection, and supplies heating heat to the room.

6 is a partial cross-sectional view showing another example of the air conditioner diffuser 31 having an automatic wind direction control function according to an embodiment of the present invention, and FIG. 7 is a wind direction control body 51 and elasticity shown in FIG. It is a perspective view which shows the holder 53 separately.

The same reference numerals as those of the above-mentioned reference numerals indicate the same members having the same function.

Referring to the drawings, it can be seen that the elastic holder 53 is installed on the top of the wind direction regulator (51). The elastic holder 53 is a belt-shaped member that has a predetermined width and thickness and is curved to conform to the upper surface of the wind direction regulator 51, and one end thereof is connected to the hinge portion 53a through the rotation shaft 53d. The other end of the elastic holder 53 is provided with a holding portion 53b.

The holding part 53b serves to elastically accommodate and support one side edge portion of the wind direction regulator 51. The holding part 53b may be retracted in the arrow z direction by an external force. Therefore, for maintenance of the diffuser or other necessity, the holding part 53b may be reclined in the direction of arrow z to align the wind direction control body 51 in the direction of arrow A.

The hinge portion 53a is a support fixed to one side of the upper surface of the wind direction control body 51 and rotatably supports the rotation shaft 53d provided at one end of the elastic holder 53. The wind direction regulator 51 is able to rotate around the rotation shaft (53d).

In addition, a male screw rod 51a is fixed to a central portion of the elastic holder 53. The male threaded rod (51a) is screwed to the lower end of the rod member 37, and serves to connect the wind direction regulator (51) to the rod member (37). The male threaded rod (51a) is coupled to the rod member 37, the wind direction control body 51 is connected to the rod member 37 can be elevated with the rod member 37.

In the present description, the reference temperature of the warm air and the cold air is determined at the time of setting the diffuser according to the user's request. The boundary temperature of the warm air and cold air is a temperature in the range of 15 ° C to 25 ° C.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Diffuser 13: Casing 13a: Air flow path
15: Wind direction control body 17: rack gear 19: pinion gear
21: motor 23: drive shaft 25: support bracket
31: diffuser 33: casing 33a: air flow path
35 frame 35a guide hole 37 rod member
37a: female thread portion 39: shape retaining spring 41: support plate
43: adjusting screw 43a: head 43b: screw thread
45: spring support 45a: through hole 47: spring support
47a: through hole 49: coil spring 51: wind direction control body
51a: Male thread rod 51b: Nut 53: Elastic holder
53a: hinge portion 53b: holding portion 53d: rotating shaft

Claims (5)

As it passes through the air supplied from the outside through the air supply duct and diffuses into the room,
A casing connected to an end of the air supply duct and passing air therein;
A frame fixed to the inside of the casing with a guide hole extending vertically;
A hollow rod member penetrating the guide hole and being capable of lifting in a state supported by the guide hole, extending in the longitudinal direction, and having upper and lower ends positioned at upper and lower portions of the frame;
A wind direction adjuster coupled to the lower end of the rod member to adjust the flow direction of the air passing through the casing by lifting up and down with the rod;
A support means provided at an upper end of the rod member and capable of adjusting a position with respect to the frame by elevating with the rod member;
Responsive to the temperature of the air supplied through the air supply duct, the shape memory spring for elastically supporting the support means in a state installed between the frame and the support means;
And a coil spring positioned between the frame and the wind direction control member to elastically support the rod member downward. The method of claim 1,
The rod member is a hollow pipe-shaped member having a rectangular cross section,
The support means is screwed to the upper end of the rod member, and includes a control screw for adjusting the distance to the frame in accordance with the degree of screwing with the rod member,
The shape memory spring, the air conditioner diffuser having an automatic wind direction control function, characterized in that up to support the adjustment screw in a state sandwiched between the head portion of the adjustment screw and the frame wrapped around the rod member. 3. The method according to claim 1 or 2,
In the upper center of the wind direction regulator, a male screw rod is fixed to the lower end of the rod member,
The coil spring, the air conditioner diffuser having an automatic wind direction control function, characterized in that sandwiched between the frame and the wind direction control body while wrapping the rod member. The method of claim 1,
The lower end of the rod member, the air conditioner diffuser having an automatic wind direction control function characterized in that it further comprises a regulator support for supporting the wind direction control body to the rod member to separate the wind direction control body from the rod member. 5. The method of claim 4,
The regulator support portion;
A male screw rod screwed to the lower end of the rod member;
As fixed to the lower portion of the male screw rod, one end of the hinge is rotatably connected to the upper surface of one side of the wind direction regulator, the other end is located on the opposite side of the hinge relative to the male threaded rod and elastically detachable to the wind direction regulator An air diffuser having an automatic wind direction control function, characterized in that it comprises an elastic holder for supporting.

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