KR100834010B1 - Tower type regulator for variable wind direction - Google Patents

Abstract

A tower type regulator for variable wind direction is provided to adjust cold/hot wind discharging angle by reflecting the characteristics of the cold and hot wind, and to distribute the load of an inner case by a buffer unit for improving the durability of a lifting unit and achieving precise manipulation. A tower type regulator for variable wind direction includes an outer case(2) formed with air outlets(22) by a constant interval in an outer peripheral surface, an inner case(4) formed with damper holes(48) and damper grills(46) corresponding to the air outlets of the outer case and inserted into the outer case, a lifting unit(6) for lifting the inner case, and a noise preventing element(8) mounted in the outer case. The damper grill is connected to an axis of an inner peripheral surface of the inner case vertically to be adjacent to upper and lower parts of the damper holes, wherein the damper grill has a section in the trapezoidal shape with inclined upper and lower surfaces. A buffer unit is mounted at a lower part in the inner case and includes a bearing supporting plate formed in the center of a lower end of the inner case and a spring(7) mounted at a lower part of the bearing supporting plate.

Description

TOWER TYPE REGULATOR FOR VARIABLE WIND DIRECTION}

The present invention relates to a tower-type variable wind direction regulator, and more particularly, to a tower-type variable wind direction regulator to improve the cooling and heating efficiency by selectively adjusting the discharge wind direction according to the cooling or heating conditions.

In general, the air conditioner for cooling or heating inside the building is composed of a duct for guiding the hot air or cold air generated from the air conditioner to the room, and a diffuser connected to the duct in each room.

Conventional ducts and diffusers are mainly installed on the ceiling or floor, which requires a lot of ducts and diffusers if the indoor space is large.

In particular, the airport or the waiting room of the history is designed to have a very high ceiling, so if you install the duct and diffuser on the ceiling, the cooling and heating efficiencies will be lost during the fall of the cooling and warm air. there was.

In order to improve this, the applicant has filed a `` tower type variable air volume regulator '' of the Republic of Korea registration 20-0394525.

9 is a view of the prior art.

Referring to FIG. 9, the four circumferential walls of the cylindrical damper 20 are perforated in multiple stages at regular intervals on the four circumferential walls of the cylinder 10 installed upright, and inserted into the cylinder 10. The damper hole 21 was drilled at a position coinciding with the air outlet 11 of the Edo cylinder 10, and a plurality of lifting rods 22 were vertically welded to the inner circumferential wall of the cylindrical damper 20. Each upper end portion 22 of 22 protrudes through the lid 12 fixed to the upper end of the cylinder 10.

And the rotating shaft 40 is horizontally installed in the bearing 30 fixed to both sides of the upper surface of the cover 12, the lifting piece 41 fixed to both ends of the rotating shaft 40 is raised on both sides of the diagonal It is connected to the guide bearing 23 of the steel bar 22, the operating shaft 51 of the damper actuator 50 which is operated by the room temperature sensor is configured to be connected to the guide section 42 fixed to the rotating shaft 40 It became.

In addition, the inner surface of the cover 12 of the cylinder 10 is narrowly formed in the lower center, and a conical silencer 60 in which sound absorbing holes 61 are arranged on the circumferential wall is fixed. 61 is arranged, and the cylindrical silencer 70 is gradually installed from the bottom to the top is gradually narrowed.

That is, it is composed of a duct embedded in the floor, and a cylinder connected to the duct and installed upright in the room, the cylinder is to control the air volume by having an opening and closing means.

Therefore, by installing in a high ceiling place by spraying the appropriate amount of cooling, hot air over the head of the person it becomes possible efficient cooling and heating.

However, the prior art has a problem that the airflow of cold or warm air is not properly injected during cooling or heating.

That is, in the case of cold wind, the specific gravity of the air is heavy, so that it sinks downward, and in the case of the warm wind, the specific gravity of the air is light, so that it floats upward. The prior art does not consider the characteristics of the cold and hot air in one direction. Only spraying has been a problem of insufficient heating and cooling efficiency.

The present invention was devised to improve the Republic of Korea Registered Application No. 20-0394525 filed by the present applicant, by adjusting the injection angle of the cold and hot air differently, the injection angle of the cold wind is further adjusted, the injection angle of the hot air It is aimed to provide a tower-type variable wind direction controller that allows the cooling air to sink more slowly from the top to the bottom, and the warm air gradually rises from the bottom to the top to increase the cooling and heating efficiency.

An object of the present invention, the outer cylinder is installed in the upright and the air outlet is perforated in multiple stages at regular intervals on the outer peripheral surface; An inner cylinder body formed with a plurality of damper holes and damper grills corresponding to the air outlets and inserted into the outer cylinder body; An elevating device installed to elevate the inner cylinder; The damper grill is installed on the inner circumferential surface shaft of the inner cylinder so as to be adjacent to the upper and lower portions of the damper hole, the cross section is trapezoidal, the inclined upper surface and the lower surface. This is achieved by a tower-type variable wind direction regulator formed.

According to the present invention, there is an effect that the cooling and heating efficiency can be increased by adjusting the spray angle of the cold, hot air to reflect the characteristics of the cold and hot air.

In addition, by providing a cushioning means to distribute the load of the inner cylinder, not only the durability of the elevator apparatus is excellent but also the sophisticated operation is possible.

The present invention, the outer cylinder is installed in the upright and the air outlet is perforated in multiple stages at regular intervals on the outer peripheral surface; An inner cylinder body formed with a plurality of damper holes and damper grills corresponding to the air outlets and inserted into the outer cylinder body; An elevating device installed to elevate the inner cylinder; The damper grill is fixedly installed inside the outer cylinder, and the damper grill is vertically connected to the inner circumferential surface axis of the inner cylinder so as to be adjacent to the upper and lower portions of the damper hole, and has a trapezoidal cross section and an inclined upper surface. And a lower surface is formed.

In the present invention, the lower portion of the inner cylinder is further provided with a cushioning means, the buffer means is characterized in that consisting of a bearing support plate formed in the lower center of the inner cylinder, and a spring provided in the lower portion of the bearing support plate.

In the present invention, the upper surface of the damper grill is characterized in that it is formed to have a slope of -7 °.

In the present invention, the lower surface of the damper grill is characterized in that it is formed to have an inclination of +15 °.

In the present invention, the elevating device is a shaft vertically installed at the lower end of the outer cylinder, a bearing for smooth up and down movement of the inner cylinder, an actuator installed to elevate the shaft, and a connecting member connecting the actuator and the shaft Characterized in that consisting of.

In the present invention, the connecting member is a shaft rod coupled to the upper support plate of the inner cylinder, a universal joint coupled to the upper end of the shaft, a first rod one end hinged to the universal joint, and the first And a rotation shaft coupled to the other end of the rod, a second rod coupled to the rotation shaft, and an actuator installed to rotate the second rod.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front sectional view of a tower type variable wind direction controller according to the present invention, FIG. 2 is a plan view of a tower type variable wind direction controller according to the present invention, and FIG. 3 is a side sectional view of a tower type variable wind direction controller according to the present invention. .

1 to 3, the tower-type variable wind direction controller (A) according to the present invention, the outer cylinder (2) is installed in the upright by the air outlet 22 is perforated in multiple stages at regular intervals on the outer peripheral surface; An inner cylinder 4 formed with a plurality of damper holes 48 and damper grills 46 corresponding to the air outlets 22 and inserted into the outer cylinder 2; An elevating device 6 installed to elevate the inner cylinder 4; It consists of a noise prevention device (8) fixedly installed inside the outer cylinder (2).

Each structure is demonstrated in detail.

The outer cylinder (2) is formed in a circular or rectangular shape, the inside is empty and connected to the duct 100, the air outlet 22 of the long hole shape is perforated horizontally on the outer peripheral surface, the air outlet 22 naturally The upper and lower portions of the stepping stones 24 are formed.

An upper plate 26 on which the elevating device 6 is installed is installed at an upper end of the outer cylinder 2, and an outer cylinder support 28 is installed at a lower portion thereof.

The outer cylinder support 28 is radially installed on the lower inner circumferential surface of the outer cylinder 2, the center is formed with a seating hole 282 to which the shaft 61 is coupled.

4 is an enlarged view showing a part of the "inner cylinder" in FIG.

Referring to FIG. 4, the inner cylinder 4 is inserted into the outer cylinder 2 and is formed in a circular or square shape having the same shape as the outer cylinder 2, and a plurality of flat iron shafts 42 vertically installed. And, the upper support plate 44 attached to the upper end of the flat iron shaft 42, and the damper grill 46 is attached to the outer surface of the flat iron shaft 42 and installed to correspond to the air outlet 22, The damper grill 46 is spaced apart at regular intervals so that the damper grill 46 is naturally adjacent to the upper and lower portions of the damper hole 48.

The damper grill 46 is a circular member spaced apart at regular intervals to form a damper hole 48 and fixed to the outer surface of the flat iron shaft 42 by riveting, and has an inclined upper surface 461 having a trapezoidal cross section. And a bottom surface 462 is formed.

Preferably, as shown in the enlarged view of FIG. 4, the upper surface 461 of the damper grill 46 is -7 ° below the horizontal line h1 when the virtual horizontal line h1 is set to 0 °. It is formed to have an inclination θ ₁ .

Further, the lower surface 462 of the damper grill 46 is formed to have an inclination θ ₂ of + 15 ° on the upper portion of the horizontal line h2 when the virtual horizontal line h2 is set to 0 °.

In addition, a bearing support plate 43 is formed at the lower center of the inner cylinder 4, and the bearing support plate 43 is supported by a plurality of inner cylinder supports 45 radially connected to the inner surface of the inner cylinder 4. A groove 432 in which the spring 7 is seated is formed at a lower portion thereof, and a through hole 434 through which the shaft 61 of the elevating device 6 penetrates is formed at the center thereof.

As shown in FIG. 1, the shaft 61 penetrates the upper support plate 44 of the inner cylinder 4 and the upper plate 26 of the outer cylinder 2, and the elevating device plate of the upper end of the outer cylinder 2. It is coupled to (68), the lower end is coupled to the mounting hole 282 formed in the outer cylinder support 28 of the outer cylinder (2) is installed vertically.

At this time, the upper end of the shaft 61 is coupled to the elevating device plate 68 connected to the outer cylinder 2, and the linear bearing 612 coupled to the upper outer circumference of the shaft 61 is the inner cylinder 4 of the Combined with the upper support plate 44, the inner cylinder 4 is smoothly moved up and down.

5 is an enlarged view showing "buffer" in FIG.

Referring to Figure 5, the buffer means for supporting the load of the inner cylinder 4 to prevent damage to the inner cylinder 4, the spring is installed to support the bearing support plate 43 of the inner cylinder (4) It consists of (7).

That is, the spring 7 is coupled to the outer circumference of the shaft 61 of the elevating device 6, the upper end is inserted into the groove 432 of the bearing support plate 43 and supported, the lower end is an outer cylinder ( It is inserted into and supported in the seating hole 282 formed in the outer cylinder support 28 of 2).

The lifting device will be described with reference to FIGS. 1 to 3 again.

1 to 3, the lifting device 6, the connecting member coupled to the upper support plate 44 of the inner cylinder 4, and actuating the connecting member to raise and lower the inner cylinder 4 The actuator 62 is comprised.

The connecting member includes a shaft rod 63 coupled to the upper support plate 44 of the inner cylinder 4, a universal joint 64 coupled to an upper end of the shaft rod 63, and one end of the universal joint 64. A first rod (65) hinged to the shaft, a rotation shaft (66) coupled to the other end of the first rod (65), a second rod (67) coupled to the rotation shaft (66), and the second It consists of an actuator 62 installed to rotate the rod 67.

The first and second rods 65 and 67 and the rotation shaft 66 are integrally coupled to each other so as to operate together with the operation of the actuator 62.

The actuator 62 preferably uses a conventional linear motor, and the tip of the movable member 622 to be drawn out and drawn in is hinged with the second rod 67. An operation description thereof will be described later.

The noise prevention device 8 is a trumpet shape that increases in diameter from the lower portion to the upper portion, and a plurality of sound-absorbing holes are formed, and a plurality of slits (not shown) through which the flat iron shaft 42 of the inner cylinder passes through the upper expansion portion. Is formed, the end of the expansion pipe is fixed to the inner peripheral surface of the outer cylinder (2).

The combination and operation of the present invention configured as described above will be described.

First, the inner cylinder 4 having the noise suppression device 8 installed therein is inserted into the outer cylinder 2, and the shaft rod 63 of the elevating device 6 is attached to the upper support plate 44 of the inner cylinder 4. ) Is inserted, the universal joint 64 is installed on the upper end of the shaft 63, and the upper end of the universal joint 64 is hinged to the first rod 65.

The first rod 65 secures one end to a horizontal rotating shaft 66 coupled to the upper plate 26 of the outer cylinder 2 by a bearing.

One end of the second rod 67 is coupled to the other side of the rotating shaft 66, and the actuator 62 is hinged to the other end of the second rod 67 after the hinge 622 of the actuator 62 is engaged. It is hinged to the upper plate 26 of the outer cylinder 2.

On the other hand, the inner cylinder 4 and the noise prevention device 8 is passed through the shaft 61 vertically in the center thereof, the upper end of the shaft 61 is the upper support plate 44 and the outer cylinder ( It is coupled through the upper plate 26 of 2), the lower end is coupled to the seating hole 282 formed in the outer cylinder support 28 of the outer cylinder (2).

At this time, the spring (7) is fitted to the lower outer surface of the shaft 61, the upper end of the spring (7) is inserted into and supported by the bearing support plate 43 of the inner cylinder (4), the lower end to the seating hole (282) Supported.

Then, the lower portion of the outer cylinder (2) is connected to the wind duct 100 which is connected to the air conditioner is installed perpendicular to the ground.

With reference to the accompanying Figures 6 to 8 will be described the operating relationship of the present invention.

Figure 6 is a view showing a "closed" state of the tower type variable wind direction regulator of the present invention.

As shown in FIG. 6, the damper grill 46 blocks the air outlet 22 of the outer cylinder 2 so that the internal air is not discharged to the outside.

That is, when the mover 622 of the actuator 62 is set to the state which is not initially drawn out, when the actuator 62 starts to operate and the mover 622 is pulled out, the inner cylinder 4 moves upwards. When the mover 622 reaches an intermediate position of the maximum and minimum travel distances, the damper grill 46 of the inner cylinder 4 blocks the air outlet 22.

7 is a view showing the "heating" operation of the tower type variable wind direction controller of the present invention.

As shown in FIG. 7, when the inner cylinder 4 rises at predetermined intervals at an intermediate position at the time of heating, the air outlet 22 and the damper hole 48 pass through, and warm air is discharged | emitted.

Looking at the ascending process of the inner cylinder 4, when the mover 622 of the actuator 62 is withdrawn at a predetermined interval from the intermediate position, the second rod 67 is rotated upwards, the rotary shaft 66 is clock Direction, the first rod 65 is rotated upwards, and the inner cylinder 4 is raised as the universal joint 64 and the shaft bar 63 rise upwards.

In particular, the lower surface 462 of the damper grill 46 is located above the lower end of the step 24 due to the rise of the inner cylinder 4, and the warm air discharged through the damper hole 48 is lowered from the lower surface ( After hitting 462 first, the direction is turned downward and discharged through the air outlet 22.

Therefore, the heating efficiency can be improved by directing more warm air to the ground by forcing the warm air having a characteristic of going up to be discharged downward.

8 is a view showing the "cooling" operation of the tower type variable wind direction controller of the present invention.

As shown in FIG. 8, when cooling, the inner cylinder 4 descend | falls in the closed state like FIG. 6 at the time of heating, the air outlet 22 and the damper hole 48 will pass, and cold air will be discharged | emitted.

Looking at the descending process of the inner cylinder (4), the second rod (67) is rotated downward, the rotating shaft 66 is rotated by the actuator 622 of the actuator 62 is lowered in the closed state as shown in FIG. It rotates in a clockwise direction, the first rod 65 is rotated downward, the inner cylinder 4 is lowered while the shaft rod 63 and the universal joint 64 is lowered.

In particular, the lower surface 462 of the damper grill 46 is positioned below the lower end of the step 24 due to the lowering of the inner cylinder 4, and the cold air discharged through the damper hole 48 is lower than the lower surface ( 462 is discharged directly through the air outlet 22 without hitting.

Thus, by discharging the cold air having a characteristic to sink to the bottom upwards as much as possible, the cooling efficiency can be improved by lowering the ejected cold wind from a higher position.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, all such modifications and modifications being attached It is obvious that the claims belong to the claims.

1 is a front sectional view of a tower type variable wind direction controller according to the present invention.

2 is a plan view of the tower-type variable wind direction regulator according to the present invention.

3 is a side cross-sectional view of a tower-type variable wind direction controller according to the present invention.

4 is an enlarged view of a portion of the “inner cylinder” in FIG. 1.

FIG. 5 is an enlarged view of the "buffer" in FIG.

Figure 6 is a view showing a "closed" state of the tower type variable wind direction regulator of the present invention.

Figure 7 is a view showing the "heating" operation of the tower type variable wind direction controller of the present invention.

8 is a view showing the "cooling" operation of the tower type variable wind direction controller of the present invention.

Explanation of symbols on the main parts of the drawings

2: outer cylinder 4: inner cylinder

6: lifting device 8: noise preventing device

22: air outlet 24: stone jaw

28: outer cylinder support 42: flat iron shaft

43: bearing support plate 44: upper support plate

46: damper grill 48: damper ball

61: shaft 62: actuator

63: shaft 64: universal joint

65: first rod 66: rotation axis

67: second rod 68: elevating device plate

Claims (8)

An outer cylinder 2 having an air outlet 22 perforated in multiple stages on an outer circumferential surface and installed upright; An inner cylinder 4 formed with a plurality of damper holes 48 and damper grills 46 corresponding to the air outlets 22 and inserted into the outer cylinder 2; An elevating device 6 installed to elevate the inner cylinder 4; It is composed of a noise preventing device (8) installed inside the inner cylinder (4), The damper grill 46 is adjacent to the upper and lower portions of the damper hole 48, is provided on the outer circumferential surface of the inner cylinder 4, has a trapezoidal cross section, and has an inclined upper surface 461 and a lower surface 462. Tower-shaped variable wind direction regulator, characterized in that formed. The method of claim 1, The upper surface 461 of the damper grill 46 is formed to have an inclination θ ₁ of −7 ° at the bottom of the horizontal line h1 when the virtual horizontal line h1 is set to 0 °. Tower variable wind direction regulator. The method of claim 1, The lower surface 462 of the damper grill 46 is formed to have an inclination θ ₂ of + 15 ° on the upper portion of the horizontal line h2 when the virtual horizontal line h2 is set to 0 °. Tower variable wind direction regulator. The method of claim 1, The outer cylinder (2), the upper and lower jaw 24 is formed in the upper and lower portions of the air outlet 22, the upper plate 26 is provided with the lifting device 6 is installed at the upper end, the outer cylinder support 28 ) Is installed, The outer cylinder support 28 is installed radially on the lower inner circumferential surface of the outer cylinder (2), the tower-shaped variable wind direction regulator, characterized in that the seating hole 282 is formed in the center. The method of claim 1, The inner cylinder 4, the upper support plate 44 is formed on the upper end of the plurality of flat iron shaft 42 is installed vertically, the bearing support plate 43 is formed in the lower center, The bearing support plate 43 is supported by a plurality of inner cylinder support 45 connected radially to the inner surface of the inner cylinder 4, the groove 432 is formed inside, the through hole 434 is formed in the center Tower type variable wind direction regulator, characterized in that. The method of claim 5, The lower end of the inner cylinder (4) is further provided with a buffer means, the buffer means is a tower type variable wind direction regulator, characterized in that the spring (7) is inserted into the groove (432) of the bearing support plate (43). The method of claim 1, The elevating device (6) is a tower-type variable, characterized in that it comprises a connecting member coupled to the inner cylinder (4), and the actuator 62 for operating the connecting member to elevate the inner cylinder (4) Wind direction adjuster. The method of claim 7, wherein The connecting member may include a shaft rod 63 coupled to the inner cylinder 4, a universal joint 64 coupled to an upper end of the shaft rod 63, and one end hinged to the universal joint 64. Rotating the first rod 65, the rotary shaft 66 coupled to the other end of the first rod 65, the second rod 67 coupled to the rotary shaft 66, and the second rod 67 Tower type variable wind direction regulator comprising an actuator (62) installed to be made.

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