KR102080273B1 - Diffser for air-conditioning - Google Patents

Abstract

The present invention relates to a diffuser for air conditioning, wherein a plurality of wings can be pivot-rotated at the same time in response to temperature to supply cold air by forming a vortex and to supply warm air without resistance. According to the diffuser for air conditioning, the plurality of wings (300) are arranged radially around an outer square pipe (410), and can be stably pivot-rotated. Moreover, rotational protrusion (320) formed in the wings (300) can pass through the outer square pipe (410) to be placed between a coil spring (430) and an inner square pipe (420) in the outer square pipe (410). In addition, the inner square pipe (420) is pressurized by a temperature sensitive cylinder (440) sensitive to temperature so that the wings (300) can be vertically erected.

Description

HVAC Diffuser {DIFFSER FOR AIR-CONDITIONING}

The present invention relates to an air conditioner diffuser that pivots a plurality of blades simultaneously in response to a temperature so as to form and supply vortex when supplying cold air and supply resistance without supplying warm air.

The central air conditioning system is configured to supply the cold or warm air generated seasonally from the air conditioner in the machine room through the duct to the diffusers installed in each room of the building.

By the way, since the cold air tends to fall and the warm air tends to rise, a vortex is formed when the cold air is supplied to the room and is evenly distributed to the indoor ceiling, and when the warm air is supplied to the room, it blows directly toward the indoor floor. Diffusers with wings to give have been developed.

The diffuser disclosed in Korean Patent No. 10-0338188 has a driving means for tilting each wing during cold air in response to the temperature of supply air, and vertically standing each wing during warm air. Such driving means is configured to accumulate vanes in a cylinder provided between a shape memory alloy coil sensitive to temperature and a bias spring providing an elastic force. However, according to the state of the temperature-sensitive shape memory alloy coil, the cylinder moves up and down, and the wing swings up and down as well, and it is unstable, and this instability requires a special structure to be built in the case, and the noise increases. There was also a problem.

In order to solve this problem, Patent Nos. 10-0597224, 10-1010029 and 10-0936785 disclose two wing portions formed by radially arranging two fixed blades and a rotating wing. And a linear motion by the temperature-sensitive drive means was converted into a rotational motion to rotate the rotary wing portion. Thereby, the wing of a rotational wing part is arrange | positioned between the wings of a stationary wing part in response to cold air, and overlaps with the wing of a stationary wing part in response to warmth. By constructing two wings as described above, the blades can be stabilized, noise is further reduced, and there is also an advantage that it can be configured as general driving means for converting linear motion into rotational motion.

However, when supplying warmth, a certain amount of wind forms an unwanted vortex by the inclined vanes, and the volume of the power transmission means for converting the linear motion into the rotational motion becomes large, which causes the amount of air flow to decrease. If the delivery means is made small, there is a problem that the durability can be lowered.

Looking at the conventional patent as described above, each wing is individually set to minimize the resistance to the heating airflow, to maintain a stable state of the wings pivoted at any angle, and to simplify the driving method for the pivot of the wing desirable.

KR 10-0338188 B1 2002.05.14. KR 10-0597224 B1 2006.06.28. KR 10-1410029 B1 2014.06.13. KR 10-0936785 B1 2010.01.06.

Accordingly, an object of the present invention is to automatically adjust the tilt angle of the radially mounted plurality of blades in response to the temperature of the supply air at the same time, to form a vortex reliably when supplying the cooling air, heating airflow when supplying the heating air Minimizing the elements hindering, simplifying the drive means for adjusting the tilt angle of the wing, to provide an air conditioner diffuser that can maintain the wing tilt angle stably.

In order to achieve the above object, the present invention provides a case 100 for forming a flow path for passing air; A hub 400 installed using the bracket 200 to be disposed on an inner center line of the case 100; In the air conditioner diffuser comprising a plurality of wings 300 disposed radially around the hub 400, the wings 300, both ends of the case 100 on the inner peripheral surface side and the hub 400 outer peripheral surface side Pivot shafts 310a and 310b which are laid out to enable pivoting, and a portion which is placed on the lower side when the wing 300 is erected among the eccentric portions with respect to the inner pivot shaft 310a facing the hub 400. The rotating protrusion 320 is formed to protrude toward the hub 400, the hub 400 is a square tube having a flat surface as many as the number of the blades 300, each of the flat surfaces of the wing 300 And having a predetermined arc angle starting from the bottom of the shaft insertion hole 411 centering on the shaft insertion hole 411 and the shaft insertion hole 411 to install the inner pivot shaft 310a of An outer shell tube 410 having a circular arc 412 formed therein; An inner corner tube 420 accommodated in the outer corner tube 410 to press the rotation protrusion 320 downward; A coil spring 430 accommodated in the outer corner tube 410 and disposed below the rotation protrusion 320 to apply a force for pushing the rotation protrusion 320 upward; A temperature sensitive cylinder 440 configured to linearly move the operation rod 442 by thermal expansion due to air temperature passing through the case 100, and press the inner tube 420 downward with the operation rod 442; And a diffuser plate 500 installed at a lower end of the outer tube 410.

According to an embodiment of the present invention, the inner corner tube 420 has an inner step 421 protruding from the inner surface of the lower opening, and the diffusion plate 500 is screwed on the lower portion of the outer corner tube 410. And having an insertion rod 510 inserted therein, the upper end of the insertion rod 510 being inserted into the inner corner tube 420 and being caught by the inner step 421. By having 520, it is possible to adjust the maximum tilt angle of the wing 300 according to the lifting height.

According to an embodiment of the present invention, the arc-shaped hole 412 of the outer tube 410 has a 90 ° arc angle, so that the blade 300 can be tilted horizontally by using the diffusion plate 500. do.

According to an embodiment of the present invention, when the wing 300 is inclined horizontally, the adjacent ones have an overlapping portion to close the inner passage of the case 100.

According to an embodiment of the present disclosure, the temperature sensitive cylinder 440 may press the safety spring 446 having a spring constant relatively larger than that of the coil spring 430 to the operation rod 442. It is mounted in a state in which the inner tube 420 is pressed in a direction opposite to the inner tube 420, so that the safety spring 446 can be contracted and pushed when the inner tube 420 is pressed by the operation rod 442.

The present invention configured as described above is a pivot for rotating the wing 300 through the arc-shaped hole 412 formed on the surface with respect to the pivot axis in a state in which the axis for pivoting the blade 300 pivotally without shaking. It is possible to stably guide and rotate (320), by using the outer angle tube 410 and the inner angle tube 420 made of a square tube shape to directly press the rotating projection 320, so as to block foreign material inflow With the structure, it is possible to minimize the malfunction caused by the inflow of foreign matters, to carry out the operation according to the temperature response stably and accurately, and also to provide the power conversion means in the middle, and to simplify the construction and the balance. Can minimize the durability.

According to an embodiment of the present disclosure, since the inclination of the blade 300 when supplying the cold air may be adjusted by the diffusion plate 500, the eddy current strength and the flow direction of the cold air may be adjusted, and thus the propensity of the installed indoor user It can supply cold air according to the indoor situation.

According to one embodiment, the present invention has a closing function to block the inflow of air, it is possible to use a variety of operating methods such as blocking the noise when not in use for air conditioning or closing the season.

According to an embodiment of the present disclosure, by adding the safety spring 446, the damage that may occur due to the over-expansion of the temperature sensitive cylinder 440 may be prevented.

1 is a top perspective view (a) and a bottom perspective view (b) of the air conditioning diffuser according to an embodiment of the present invention.
Figure 2 is a perspective view showing only the components mounted inside the case 100, a perspective view (a) with the wing 300 inclined at a predetermined angle (a) and a perspective view (b) with the wing 300 in a vertical position.
3 is a view showing a process of laying the wing 300 in the outer shell 410 of the hub 400.
Figure 4 is a cross-sectional view (a) and a partially cut perspective view (b) of the air conditioning diffuser according to an embodiment of the present invention.
5 is a partially enlarged view of a portion A in which the hub 400 is installed in FIG. 4 (a).
6 is a partially enlarged view of a portion B in which the hub 400 is installed in FIG. 4 (b).
7 is a side view and a sectional view showing an operating state when supplying warmth.
8 is a side view and a sectional view showing an operating state when supplying cold air;
9 is a side view and a cross-sectional view showing an operating state when closing the air conditioning diffuser.
10 is a cross-sectional view of the air conditioning diffuser according to a modified embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

1 is a perspective view (a) showing a state of the air conditioner diffuser according to an embodiment of the present invention as seen from the upper side and a perspective view (b) showing a state seen from the bottom side.

Figure 2 is a perspective view showing only the components mounted inside the case 100, a perspective view (a) of the blade 300 is inclined at a predetermined angle as the cold air is supplied, and the temperature-sensitive cylinder sensitive to warmth The perspective view (b) of the state in which the wing 300 is standing vertically by 440 is shown.

1 and 2, the air conditioner diffuser according to an embodiment of the present invention bracket 200, the wing 300 in the inner hollow of the case 100 formed of a hollow tube to form an air flow path ) And a hub 400, and the diffusion plate 500 is disposed at one opening through which air is discharged.

The case 100 has a structure in which the air supplied from the machine room air conditioner is connected to the duct to diffuse and supply the air to the room. The case 100 is not limited to the form shown in FIG. 1 and may be modified in various forms. For example, the case 100 is not limited to a cylindrical type but may also be a square type, and the inlet 101 of one side through which air is introduced from the air conditioner in various forms for duct connection. It may be deformed, and the expansion pipe shape of one side outlet 102 for discharging air may be deformed.

The hub 400 is disposed along the inner center line of the case 100, and fixed to the middle of the bracket 200 fixed to the case 100 in a form crossing the inside of the case 100. have.

In terms of appearance, the hub 400 protrudes toward the air inlet 101 of one side of the case 100 around the outer angle pipe 410 and the outer angle pipe 410 extending in the air flow direction. The diffusion plate 500 is provided at a portion of the sensing cylinder 440 that faces the air outlet 102 on the other side. As described in detail below, the inner corner tube 420 and the coil spring 430 are accommodated in the outer corner tube 410.

The wings 300 are provided in plural and are disposed radially about the hub 400. Each vane 300 is built on the inner circumferential surface side of the case 100 and the outer surface side of the outer tube 410 of the hub 400, and is perpendicular to the state inclined at a predetermined angle as shown in FIG. Pivot rotation is possible to place any one of the states.

Such a change in state of the blade 300 is determined according to the temperature sensed by the temperature sensitive cylinder 440, as described later, and the inclined predetermined angle is adjusted by the diffusion plate 500. .

In order to pivot the movement of the wing 300, an inner circumferential surface of the case 100 is provided with an annular bracket 210 to be installed on the wing 300, the annular bracket 210 to the bracket 200 By the connecting bracket 220, the annular bracket 210 and the bracket 200 were configured integrally. Accordingly, the hub 400 may be fixed to the bracket 200, and the plurality of wings 300 may be assembled in the state of FIG. 2 installed radially around the hub 400, and then installed in the case 100. have. Here, since the female threaded portion 202 is formed in the connection bracket 220 and the annular bracket 210 in contact with the inner circumferential surface of the case 100, the female threaded portion 202 is formed by passing the bolt 201 through the case 100. The internal component assembly of FIG. 2 may be fixedly installed to the inside of the case 100 by screwing in.

In addition, in the process of assembling the internal component assembly of FIG. 2, the relative positions of the bracket 200 to which the annular bracket 210 and the hub 400 are to be fixed may be made constant, which will be described later. As described above, the relative position of the blade 300 and the temperature sensitive cylinder 440 to be accurately aligned in order to pivot the blade 300 accurately with the temperature sensitive cylinder 440 of the hub 400 may be accurately matched during the assembly process.

Hereinafter, with reference to the structure for the pivoting movement of each of the wings 300 will be described in detail.

FIG. 3 is a view illustrating a process of forming the wing 300 in the outer corner tube 410 of the hub 400.

Referring to FIG. 3, the wings 300 may pivot by forming both ends of the outer side facing the case 100 and the inner side facing the hub 400 on the inner circumferential surface side of the case 100 and the outer circumferential surface side of the hub 400, respectively. Outer tube of the hub 400 on the inner and outer pivot shafts 310a and 310b and a portion which is placed on the lower side when the wing 300 is erected among the parts eccentric with respect to the inner pivot shaft 310a. The rotation protrusion 320 which protruded toward the 410 is provided. That is, the wing 300 is provided with a pivoting projection 320 at a portion facing the outer angle tube 410 of the hub 400, the arc for the pivoting projection 320 around the pivot shaft 310 By rotating in the direction it can pivot the movement of the blade (300).

In addition, the outer corner tube 410 of the hub 400 is composed of a square tube having a flat surface as many as the number of the blades 300, the shaft insertion to insert the inner pivot shaft 310a in each flat surface An arc-shaped hole 412 is formed to draw a circular arc of a predetermined angle around the shaft insertion hole 411 and the shaft insertion hole 411 so as to be rotatable while the rotation protrusion 310 is fitted. .

Here, the pivoting projection 320 of the wing 300 passes through the arc-shaped hole 412 so as to protrude a predetermined length into the outer tube 410, relative to the inner pivot shaft 310a It is made longer.

According to the embodiment of the present invention, since the arc-shaped hole 412 is formed to have a predetermined arc angle starting from below the shaft insertion hole 411, the circle in the state that the wing 300 is upright It may be inclined by an angle corresponding to the whistle.

According to a specific embodiment, since the arc-shaped hole 412 has an arc angle of 90 ° to reach the lateral direction of one side, the blade 300 is inserted into the arc-shaped hole 412 for the rotation projection (320). ) Can be pivoted by 90 °, so that the wing 300 can be vertically or horizontally tilted.

Of course, it is possible to pivot the blade 300 by using a line passing through the pivot shafts 310 and 310b respectively formed on the inner and outer sides of the blade 300 as an axis.

On the other hand, the outer tube 410 is provided with a bolt 414 penetrates the outer peripheral surface of the lower side, the bolt 414 at this time is for fixing the nut 413 to be inserted into the lower opening as described later.

4 is a cross-sectional view (a) and a partially cut perspective view (b) of an air conditioning diffuser according to an embodiment of the present invention.

5 is a partially enlarged view of a portion A in which the hub 400 is installed in FIG. 4 (a).

FIG. 6 is a partially enlarged view of a portion B in which the hub 400 is installed in FIG. 4 (b).

4 to 6 illustrate a state in which warm air is introduced and the temperature sensitive cylinder 440 of the hub 400 operates. That is, the temperature-sensitive cylinder 440 is operated to show a state in which the wing 300 is standing vertically.

In addition, as can be seen in Figure 3, in the embodiment of the present invention, since the arc-shaped hole 412 is made as large as possible by utilizing the outer flat surface of the outer tube 410 as much as possible, the pivot axis of the wing 300 The portions 310a and 310b are slightly displaced from the inner center of the outer tube 410 of the hub 400. Therefore, it should be noted that the partially cutaway cross-sectional views shown in FIGS. 4 (b) and 6 are displaced from each other so as to pass through the opposing opposite side insertion holes 411.

Referring to FIG. 4, as described with reference to FIG. 2, a bracket for connecting the bracket 200 to which the hub 400 is fixed and the annular bracket 210 for forming the outer pivot shaft 310b of the wing 300 are connected. After integrating with (220), it was fixed to the case (100) with a bolt (201). Here, the shaft insertion groove 211 is formed on the inner circumferential surface of the annular bracket 210 to insert the outer pivot shaft 310b. However, it is not necessary to limit to the expansion method of such an outer side pivot axis 310b. For example, for convenience of assembly, the outer pivot shaft 310b may be formed of a bolt so as to be screwed to the blade 300 in a state where the annular bracket 210 is pivotably penetrated from the outer circumferential surface side. . Alternatively, the shaft insertion groove 211 is formed into an elongated groove having an upper side or a lower side opened, and the inner pivot shaft 310a is formed in the outer corner tube 410 of the hub 400 and the outer side thereof. The pivot shaft 310b may be fitted and the opening on the upper side or the lower side may be closed.

In addition, since the hub 400 is fixed to the bracket 200 so as to stand vertically along the center of the air passage from the one inlet 101 to the other outlet 102 in the case 100, the hub 200 is fixed to the bracket 200. It is disposed along the inner center line of the case 100.

The hub 400 will be described with reference to FIGS. 5 and 6, which are partially enlarged.

The hub 400 is the outer angle tube 410 and the temperature-sensitive cylinder 440 and the inner angle tube 420 and the coil accommodated inside the outer angle tube 410, which are outlined with reference to FIGS. 1 to 3. It includes a spring 430, and is coupled to the diffuser plate 500 is inserted from below to upward. Considering the assembly process of the embodiment and the components included in the hub 400 and the diffusion plate 500 coupled to the hub 400 will be described in more detail as follows.

The outer corner tube 410 is configured in the shape of the upper and lower opening of the square tube having one flat surface in the direction toward each wing 300 by the number of the blades 300 to be disposed radially, the upper end to the bracket 200 It is fixed through. As described above, the shaft insertion hole 411 and the arc-shaped hole 412 are formed in each flat surface. Although the structure for fixing the outer corner tube 410 to the bracket 200 is not shown, it may be welded to join or fixed by a separate fastening means.

A nut 413 having a female thread is inserted into a lower end of the outer tube 410, and a bolt 414 inserted from an outer side is inserted into the nut 413 to be screwed in to rotate the nut 413. To be fixed. At this time, the nut 413 is installed after accommodating the coil spring 430 therein. In the embodiment, since the outer tube 410 is composed of a hexagonal tube, the nut 413 is a hexagonal nut.

The inner square tube 420 has the same number of flat surfaces as the outer square tube 410, and has a relatively short size and a relatively short length so that the flat surfaces face each other in and out of the outer square tube 410. When accommodated inside of, the rotation allows a slight rotation by the play, but the rotation angle is limited by the square tube shape.

Then, the lower opening of the inter tube 420 was bent inward to form an internal step 421 that protrudes inward.

The inner square tube 420 configured as described above has the inner pivot shaft 310a of the blade 300 built into the shaft insertion hole 411 and the pivoting protrusion 320 penetrated through the arc-shaped hole 412. The inside of the outer shell tube 410 is accommodated through the upper opening of the outer shell tube 410, so as to span the rotation protrusion 320 protruding into the outer shell tube 410. Thus, as described later, the inner tube 420 may be pressed from the upper portion to the temperature sensitive cylinder 440 to press the rotation protrusion 320 downward.

The coil spring 430 is a spring that exerts an elastic restoring force by pressing, and is accommodated in the outer corner tube 410 through a lower opening of the outer corner tube 410 to be caught by the rotation protrusion 320. do. According to an embodiment, the flat washer 431 is first received before the coil spring 430, so that the flat washer 431 is interposed between the coil spring 430 and the pivoting protrusion 320.

After accommodating the coil spring 430 in the outer tube 410, the nut 413 is inserted into the lower opening of the outer tube 410 to compress the coil spring 430, and then the nut ( By fixing the 413 to the outer tube 410, a force that pushes the pivoting projection 320 upward by a force by the elastic restoring force of the coil spring 430.

The diffusion plate 500 is a conventional configuration for diffusing air discharged from the diffuser, and is not limited to the form shown in the drawings, but may be applied by taking an appropriate form among various forms conventionally used.

However, according to the present invention, the diffusion plate 500 is configured to be mounted on the lower end of the outer tube 410, and is also used as a means for adjusting the inclination angle of the blade 300 when supplying cold air.

The diffusion plate 500 for this purpose is provided with a protruding rod 510 to be inserted into the outer tube 410 through the nut 413 inserted into the lower opening of the outer tube 410 to protrude upward. And a flat surface 501 facing the nut 413 to limit the depth at which the flat surface 501 comes into contact with the nut 413 to a maximum insertion depth.

The insertion rod 510 is provided with a male screw portion 511 at a lower portion penetrating the nut 413 of the outer leg tube 410 to be screwed, and thus, the insertion depth into the outer leg tube 410. That is, the lifting height can be adjusted by forward and reverse rotation.

The upper end of the insertion rod 510 inserted into the outer tube 410 penetrates the coil spring 430 and the flat washer 431 sequentially, and then inserts the inner tube 420 to the inside of the inner tube 420. The upper extension 520 is provided to be caught by the inner step 421 of the inner tube 420. According to the embodiment of the present invention, the upper extension part 520 is inserted through the upper opening of the outer corner tube 410, and bolts 521 on the top of the insertion rod 510 accommodated in the inner corner tube 420. ) Fastened by fastening.

Accordingly, even if the inner square tube 420 is pushed upward by the elastic restoring force of the coil spring 430, the inner step 421 is caught by the upper extension 520, thereby restricting movement to the upper portion. . That is, by rotating the diffusion plate 500 having the insertion rod 510, by adjusting the height of the upper expansion portion 520, it is possible to limit the height that the inner tube 420 can be elevated. As a result, the rotation protrusion 320 of the wing 300 is limited to the height that can be lifted to the maximum by the upper end portion 520, the maximum tilt angle of the wing 300 is also adjusted.

According to the exemplary embodiment of the present invention, since the arc-shaped hole 412 of the outer tube 410 through which the pivoting protrusion 320 of the wing 300 penetrates is formed at an arc angle of 90 °, the wing 300 ) Can be adjusted up to 90 ° by using the diffusion plate 500, and, in turn, can make the wing 300 horizontally.

Here, the wing 300 may close the inner passage of the case 100 by having a portion overlapping the adjacent ones when tilted horizontally. For example, in the embodiment of the present invention, since the outer tube 410 in the form of a hexagonal pipe is used, and six wings 300 are installed, each wing 300 is slightly larger than 360 ° / 6 = 60 °. By having it have an arc angle, it can have an overlapping part.

The temperature sensitive cylinder 440 includes a storage container 441 filled with a heat medium 441a capable of thermal expansion in response to a temperature, and an operation rod 442 pushed out to the outside by thermal expansion of the heat medium 441a. Thus, the working rod 442 is reciprocated in accordance with the external temperature. Here, as the heat medium 441a, for example, wax having a high thermal expansion rate can be used. Since the temperature-sensitive cylinder 440 is also known by the Patent Nos. 10-1410029 and 10-0936785 mentioned in the background of the present invention, a detailed description thereof will be omitted.

However, in the present invention, the temperature sensitive cylinder 440 is provided with a pressure plate 443 at the end of the operating rod 442, the difference in that the inner tube 420 is configured to press the pressure plate 443.

The temperature sensitive cylinder 440 configured as described above is installed in such a manner as to vertically install the operation rod 442 to be inserted into the outer tube 410 and then fix the reservoir 441 to the bracket 200. do. As a method of fixing to the bracket 200, a flange 441b is formed on the outer circumferential surface of the reservoir 441 as illustrated in the drawing, and the bolt 200 passes through the flange 441b. ) Can be fixed by screwing.

The temperature sensitive cylinder 440 installed as described above may lower the inner square tube 420 by pressing the pressure plate 443 when supplying warmth.

The state of the wing 300 according to temperature will be described in detail with reference to FIGS. 7 and 8.

7 is a side view and a cross-sectional view showing an operating state when supplying warmth.

8 is a side view and a cross-sectional view showing an operating state when supplying cold air.

7 and 8 omit the case 100 and the annular bracket 210 in order to more easily recognize the operating state, and only a pair of wings 300 facing each other among the plurality of wings 300. As shown in the drawings, it should be noted that the side view and the cross-sectional view are shown in one drawing.

Referring to FIG. 7, since the warm air is being supplied, the temperature sensitive cylinder 440 presses down the inner corner pipe 420 with the operation rod 442 to lower it. Accordingly, the rotation protrusion 320 of the wing 300 is pressed by the inner corner tube 420 to contract the coil spring 430 and is placed on the lowermost side of the arc-shaped hole 412 of the outer corner tube 410, and the wing 300 is erected vertically.

Therefore, the warmth passes through the case 100 without being disturbed by the wings 300. That is, when the air conditioner diffuser according to the present invention is installed on the indoor ceiling, the warm air having a tendency to rise compared to the cold air in the room is blown toward the indoor floor, thereby effectively heating the entire room.

Referring to FIG. 8, since the cold air is being supplied, the operating rod 442 of the temperature sensitive cylinder 440 is in an elevated state. Thus, the inner square tube 420 can be freely lifted up, so that the rotation projection 320 of the wing 300 is pushed up by the elastic restoring force of the coil spring 430 while pushing the inner square tube 420 upward. At this time, the pivoting projection 320 of the wing 300 is guided along the arc-shaped hole 412 of the outer angle tube 410 is raised in an arc, eventually, the wing 300 is gradually inclined.

In addition, since an upper end portion 520 is installed at an upper end of the insertion rod 510 formed to be connected to the diffusion tube 500, when the inner step 421 of the inner corner tube 420 is caught by the upper end portion 520. , The inner corner tube 420 is no longer raised, the rising projection 320 of the wing 300 also stops.

Referring to FIG. 8, the wing 300 is inclined by approximately 50 ° in the vertical state. At this time, by adjusting the depth of the insertion rod 510 is inserted into the outer tube 420, by adjusting the height of the upper extension 520 installed on the top of the insertion rod 510, the tilt of the wing 300 You can change it. Of course, the height of the upper extension 520 can be adjusted by rotating the diffuser plate 500 forward and backward.

Since the wing 300 is inclined when supplying the cold air, the supply cold air passes through the case 100 and forms a vortex by the wing 300. That is, when the air conditioner diffuser according to the present invention is installed on the indoor ceiling, since the cold air that tends to descend compared to the hot air in the room forms a vortex and is evenly dispersed in the ceiling, the air conditioner can effectively cool the entire room. Can be. In addition, by rotating the diffusion plate 500, it is possible to adjust the strength of the vortex according to the indoor situation.

9 is a side view and a cross-sectional view showing an operating state when closing the air conditioning diffuser.

Looking at Figure 9, it shows a state in which the insertion rod 510 connected to the diffusion plate 500 is inserted into the outer tube 410 as much as possible. That is, the flat surface 501 of the diffuser plate 500 is rotated by rotating the nut 413 of the outer square tube 410 and the insertion rod 510 screwed into the male screw portion 511 to be inserted. It comes in contact with the nut 413 of the tube 410. Thus, the upper expansion portion 520 installed on the top of the insertion rod 510 can be as high as possible.

At this time, the height of the upper expansion portion 520 to the height of two wings 300 in a horizontal state. That is, as shown in FIG. 9, the pivoting projection 320 of the blade 300 is placed at the highest position among the arc-shaped holes 412 of the outer corner tube 410, thereby pivoting the pivot shaft 310a of the blade 300. ) And the rotational projection 320 are at the same height. Since the inner square tube 420 should be pushed up by the rotation protrusion 320, the temperature sensitive cylinder 440 does not operate by the low temperature air, thereby preventing the inner square tube 420 from being pressurized. The state should be maintained.

As such, the function of allowing the air passage of the case 100 to be closed by using the diffusion plate 500 may be utilized, for example, in a season without a diffuser, and is not used even in summer. It can be used to close the diffuser. By having the function of closing in this way, the noise generated through the diffuser not in use can be reduced.

10 is a cross-sectional view of an air conditioning diffuser according to a modified embodiment of the present invention.

Referring to FIG. 10, the temperature sensitive cylinder 440 is pressed against the bracket 200 in a state in which a safety spring 446 is pressed in a direction opposite to the inner tube 420 to be pressed by the operation rod 442. It is mounted so that it can flow to the top, and the top is not installed higher than the bracket 200.

To this end, the bracket 200 is bisected on the basis of the temperature-sensitive cylinder 440, and has a bent piece 203 extending downward from the portion facing each other (that is, the discharge port 102 direction).

The temperature sensitive cylinder 440 is inserted between the two bent pieces 203 so that the storage container 441 covers the lower ends of the two bent pieces 203, and a safety spring 446 is provided on the outer circumferential surface of the storage container 441. To extrapolate, the safety spring 446 is contracted by a spring pressing piece 445 fixed to the bracket 200 by bolts 444.

In detail, both side bent pieces 203 protrude in the mutually opposite directions so that the step 204 is formed, and the upper end surface of the outer corner tube 410 is joined to the step 204, and the storage container 441 is formed. To span the step 204. The reservoir 441 has a flange 441b to protrude to the outer circumferential surface thereof so as to extend over the step 204 of the bent piece 203, and the reservoir 441 is provided with a safety spring 446 that allows the lower portion to extend over the flange 441b. ). The spring pressing piece 445 had a portion to be fitted in the gap between the bent piece 203 and the reservoir 441 and was fixed to the bracket 200 in a state where the safety spring 446 was pressed.

Here, the safety spring 446 used a coil spring having a relatively large spring constant compared to the coil spring 430 accommodated in the outer tube 410. Accordingly, as shown in FIG. 7, when the temperature sensitive cylinder 440 operates to contract the coil spring 430, the contraction length of the safety spring 446 is insignificant, so that the wing 300 may be vertically placed. It was.

The safety spring 446 constructed and installed in this way is for preventing damage caused by overexpansion of the heat storage member 441a of the storage container 441. That is, when the temperature sensitive cylinder 440 is sensitive to warmth, as shown in FIG. 7, the operation of the temperature sensitive cylinder 440 should be stopped in a state in which the wing 300 is vertically set up, but the heat medium 441a of the storage container 441 is heated by high temperature warmth. ) Overexpanded, the rotation projection 320 may be bent or otherwise cut. However, even if the length of the operation rod 442 with which the heat medium 441a of the storage container 441 is over-expanded and withdrawn from the storage container 441 is longer than that shown in FIG. Since the safety spring 446 is pushed back to the upper portion, it is possible to prevent the damage of the rotation protrusion 320 of the wing 300.

Of course, since the storage cylinder 441 of the temperature sensitive cylinder 440 covers a part of the outer circumferential surface by the bending piece 203 of the bracket 200, the storage cylinder 441 is sufficiently covered by the heat of warmth in a portion not covered by the bending piece 203. The reaction can thermally expand the internal heat medium 441a.

In addition, although not shown in the figure, the storage cylinder 441 of the temperature-sensitive cylinder 440 is configured to have a structure such that it is not separated between the two bending pieces 203. For example, a groove for guiding the up and down flow of the reservoir 441 may be formed in the inner circumferential surface of the bent piece 203, and a protrusion fitted into the groove may be formed in the flange 441b of the reservoir 441.

In addition, the vertical length of the operation rod 442 and the outer tube 410 is configured to have a relatively short length compared to the embodiment described with reference to FIGS.

10 may also be modified. For example, the bending piece 203 for installing the safety spring 446 is bonded to the upper end of the outer tube 410 to form a component of the hub 400, and the hub 400 having the safety spring 446. The bent piece 203 can be installed in a manner that is fixed to the bracket 200. In other words, the temperature-sensitive cylinder 440 is mounted to compress the safety spring 446 in a direction opposite to the inner tube 420 to be pressurized by the actuating rod 442 so that the inner rod is actuated by the actuating rod 442. It is satisfied that the safety spring 446 can be retracted and pushed when the tube 420 is pressed.

As another variation, the reservoir 441 of the temperature sensitive cylinder 440 may be bent horizontally to have a portion fixed along the upper surface of the bracket 200. In this case, the storage container 441 may increase the amount of the heat medium 441a to be filled therein while increasing the overall length and decreasing the outer diameter.

Meanwhile, a contact portion between the inner corner tube 420 and the actuating rod 442 pressing plate 443, a contact portion between the inner corner tube 420 and the rotation protrusion 320, and a rotation protrusion 320 and a flat washer ( At least one of the contact portions between the 431 and the rubber elastic material may be interposed therebetween. On the other hand, the shock absorbing material can be installed on the coil spring 430 up and down. Such cushioning material is for noise reduction.

Although specific embodiments have been shown and described in order to illustrate the technical idea of the present invention, the present invention is not limited to the same configurations as the specific embodiments as described above, and various modifications may be made without departing from the scope of the present invention. Can be. Accordingly, such modifications should also be regarded as falling within the scope of the present invention, and the scope of the present invention should be determined by the claims that follow.

100: case 101: inlet 102: outlet
200 Bracket 201 Bolt 202 Female thread part
203: bending piece 204: step
210: annular bracket 211: shaft insertion groove 220: connection bracket
300: wing 310a, 310b: pivot axis 320: pivoting projection
400: Hub
410: Outer corner tube 411: Shaft insertion hole 412: Arc hole
413 Nut 414 Bolt
420: inner corner 421: internal step
430: coil spring 431: flat washer
440: temperature sensitive cylinder 441: reservoir 441a: heat medium
442: operating rod 443: pressure plate 444: bolt
445: spring pressing piece 446: safety spring
500: diffuser plate 501: flat surface
510: insertion rod 511: male thread
520: upper extension 521: bolt

Claims (5)

A case 100 forming a flow path through which air is to be passed; A hub 400 installed using the bracket 200 to be disposed on an inner center line of the case 100; In the air-conditioning diffuser comprising a; a plurality of wings 300 disposed radially about the hub 400,
The wing 300 is
Of the parts eccentric with respect to the pivot axis (310a, 310b) and the inner pivot axis (310a) toward the hub 400, both ends are arranged on the inner peripheral surface side of the case 100 and the outer peripheral surface side of the hub 400 to enable pivoting. It is provided with a rotation projection (320) formed to protrude toward the hub 400 at the portion which is placed on the lower side when the wing 300 is up,
The hub 400 is
An angle pipe having a flat surface as many as the number of the blades 300, each of which has a shaft insertion hole 411 and the shaft insertion hole for laying out the inner pivot axis 310a of the blade 300; An outer corner tube 410 having an arc-shaped hole 412 formed below the shaft insertion hole 411 with a center of the 411 and having a predetermined arc angle;
An inner corner tube 420 accommodated in the outer corner tube 410 to press the rotation protrusion 320 downward;
A coil spring 430 accommodated in the outer corner tube 410 and disposed below the rotation protrusion 320 to apply a force for pushing the rotation protrusion 320 upward;
A temperature sensitive cylinder 440 configured to linearly move the operation rod 442 by thermal expansion due to air temperature passing through the case 100, and press the inner tube 420 downward with the operation rod 442; And
A diffusion plate 500 installed at a lower end of the outer tube 410;
Containing
Air Diffuser. The method of claim 1,
The inner tube 420 is
An inner step 421 protruding from an inner surface of the lower opening,
The diffusion plate 500 is
It is provided with an insertion rod 510 which is screwed in the lower portion of the outer tube 410 and is inserted and liftable by rotation, and an upper end of the insertion rod 510 is inserted to the inside of the inner tube 420 and the By having an upper extension 520 to be caught on the inner step 421, it is possible to adjust the maximum tilt angle of the wing 300 according to the lifting height
Air Diffuser. The method of claim 2,
The arc-shaped hole 412 of the outer tube 410 is
By having a 90 ° arc angle, the blade 300 can be tilted horizontally using the diffusion plate 500.
Air Diffuser. The method of claim 3, wherein
The wing 300 is
When tilted horizontally, the adjacent ones have overlapping portions so that the inner passage of the case 100 can be closed.
Air Diffuser. The method of claim 1,
The temperature sensitive cylinder 440 is
In a state in which the safety spring 446 having a spring constant relatively larger than that of the coil spring 430 is pressed toward a direction opposite to the inner tube 420 to be pressed by the operation rod 442. Mounted to allow the safety spring 446 to be retracted and pushed when pressing the inner tube 420 with the actuating rod 442.
Air Diffuser.

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