KR20100077323A - Auto-ventilation device - Google Patents

Abstract

PURPOSE: A natural ventilation device is provided to automatically control the opening degree of a vent hole opening depending on the flow of air ventilated through the vent hole. CONSTITUTION: A natural ventilation device comprises a main body(A), a flap, and an actuator(C). A vent hole(11) is formed in the main body and passes through the front and rear surfaces of the main body. The flap is formed inside the main body and opens and closes the vent hole. The actuator is formed inside the main body and operates the flap. The actuator is composed of a connection unit(100) and a driving unit(200). The connection unit is formed in an end block of the main body and is connected to the flap. The driving unit is connected to the connection unit and rotates the flap.

Description

Natural ventilation device {Auto-ventilation device}

The present invention relates to a natural ventilation device of a new structure that can automatically adjust the opening and closing degree of the vent according to the temperature difference between the indoor and outdoor or the air flow through the vent.

In general, the natural ventilation device installed on the wall surface of the building to allow for natural ventilation using the pressure difference between the indoor and outdoor, as shown in Figs. 1 to 3, the vent hole 11 passing through the front and rear surfaces It is formed and the body (A) is embedded in the wall surface (1); A flap (B) provided inside the main body (A) to open and close the vent hole (11); It is provided in the main body (A) is composed of an operating mechanism (C) for operating the flap (B) in the front-back direction.

At this time, the main body (A) is produced by extruding aluminum and the like, and the vent hole (11) formed so as to penetrate the front and rear surfaces, and the end block of the synthetic resin material coupled to both ends of the vent part (10) It consists of (20), by cutting the vent 10 to a suitable length, by combining the end block 20 to both ends of the vent 10, it is configured to be able to adjust the overall length of the body (A) .

The flap (B) is produced by extruding elastic synthetic resin or rubber in a long plate shape, is cut to fit the length of the vent 10, the upper end of the inside of the vent 10 Is hinged to the formed hinge portion 21, the lower end is rotated in the front and rear direction, it is configured to open and close the vent hole 11 formed in the vent (10).

The operating mechanism (C) is rotatably coupled to the end block (20) of the main body (A) and the rotating block 30 is provided with a hinge protrusion 31 is coupled to one side of the flap (B) on one side; , Consisting of a control lever 40 extending forward of the end block 20 at one side of the rotary block 30, the user by rotating the operation lever 40 in the vertical direction, the flap (B) You can move forward and backward.

In addition, the natural ventilation device configured as described above is mainly installed such that the front surface of the window is exposed to the interior (IN) and the rear surface of the natural ventilation device (OUT).

Therefore, when the user operates the operation lever 40 to retract the flap (B), the vent hole 11 is opened, and the indoor and outdoor air is circulated through the vent hole 11 to naturally ventilate. When the user operates the manipulation lever 40 to advance the flap B, the vent hole 11 may be closed to stop the ventilation.

By the way, such a natural ventilation device because the user manually opens and closes the vent hole 11 by moving the flap (B) back and forth with the operation lever 40, the user does not manually operate the operation lever 40 As described above, there is a problem that the ventilation is continuously made even when the indoor or outdoor temperature is significantly different by cooling or heating the room, thereby increasing the cooling and heating costs. In particular, when the indoor and outdoor temperatures are different from each other, a difference occurs in the density and pressure of the indoor and outdoor air, so that the indoor and outdoor air is more smoothly ventilated through the vent hole 11, and thus the heat loss is further increased.

The present invention is to solve the above problems, to provide a natural ventilation device of a new structure that can automatically adjust the opening and closing degree of the ventilator according to the temperature difference between the indoor and outdoor or the air flow through the ventilator The purpose is.

The present invention for achieving the above object, and the main body (A) is formed in the ventilating hole (11) penetrating the front and rear surfaces and embedded in the wall surface (1); A flap (B) provided inside the main body (A) to open and close the vent hole (11); In the natural ventilation device is provided in the main body (A) and includes an operating mechanism (C) for operating the flap (B) in the front-rear direction, the air outside the room can be ventilated,

The operating mechanism (C) is provided in the main body (A) and the connection unit 100 connected to the flap (B); An end portion is installed to be exposed to the front surface of the main body (A) and is stretched according to the indoor temperature. It includes a stretchable outdoor side expansion and contraction unit 230, the connection unit 100 is connected to the connection unit 100 by the expansion and contraction of the indoor heat expansion unit 220 and the outdoor heat expansion unit 230 There is provided a natural ventilation device comprising a drive unit (200) for operating.

According to another feature of the invention, the main body (A) is formed in the vent hole 11 penetrating the front and rear surfaces and embedded in the wall surface (1); A flap (B) provided inside the main body (A) to open and close the vent hole (11); In the natural ventilation device is provided in the main body (A) to operate the flap (B) in the front and rear direction, and to allow the air outside the room, the operating mechanism (C) is A connection unit (100) provided on the main body (A) and connected to the flap (B); It is provided in the main body (A) and is connected to the connection unit 100 includes a fan 270 that is rotated by the flow rate or flow rate of the air ventilated through the vent (11) to operate the connection unit 100 There is provided a natural ventilation device comprising a.

According to another feature of the invention, the connection unit 100 is slidably mounted to the main body (A) in the front and rear direction is connected to the drive unit 200 and the cam plate formed with a cam 111 on one side ( 110 and a cam pin 121 is inserted into the cam 111 is provided with a natural ventilation device comprising a rotating arm 120 connected to the flap (B).

According to another feature of the invention, the operation unit is connected to the connecting unit 100 or the flap (B) and extended in front of the main body (A) to allow the user to manually operate the flap (B) There is provided a natural ventilation device further comprising (300).

According to another feature of the invention, the connection unit 100 is characterized in that the clutch mechanism 126 for selectively transmitting or releasing the action of the drive unit 200 to the flap (B) is provided A natural ventilation device is provided.

In the natural ventilation device according to the present invention using the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 or the fan 270, the air circulated through the temperature difference between the indoor and outdoor or through the vent 11 In accordance with the automatic flap (B) forward and backward to adjust the opening degree of the vent hole 11, there is an advantage that can prevent the increase in heating and cooling costs due to heat loss.

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

4 to 7, the natural ventilation device according to the present invention includes a main body A formed with a ventilation hole 11 penetrating the front and rear surfaces and embedded in the wall surface 1; A flap (B) provided inside the main body (A) to open and close the vent hole (11); It is the same as that of the prior art including the actuation mechanism C which is provided in the main body A, and operates the said flap B in the front-back direction.

At this time, the main body (A) is produced by extruding aluminum and the like, and the vent hole (11) formed so as to penetrate the front and rear surfaces, and the end block of the synthetic resin material coupled to both ends of the vent part (10) It consists of 20. And, the flap (B) is formed in an elongated plate shape and the upper end is hinged to the hinge portion 21 formed on the upper side of the inside of the vent 10, when the lower end is rotated forward of the vent 10 The vent hole 11 is closed, and when the lower end rotates backward, the vent hole 11 of the vent part 10 is opened.

And, according to the present invention, the operating mechanism (C) is provided in the end block 20 of the main body (A) and the connecting unit (100) connected to the flap (B); The drive unit 200 is connected to the connection unit 100 and rotates the flap B by advancing the connection unit 100 back and forth according to a temperature difference between indoors and outdoors.

As shown in FIG. 5, the connecting unit 100 is slidably mounted to the end block 20 in a forward and backward direction and connected to the driving unit 200, and a cam plate having a cam 111 formed on one side thereof. 110 and a cam pin 121 is inserted into the cam 111 is composed of a rotating arm 120 connected to the flap (B). The cam plate 110 is inserted into a slide groove (not shown) formed at the side of the end block 20 of the main body A to be slidably mounted in the front and rear directions of the end block 20, and to the driving unit 200. Is connected and slides in the front-rear direction of the end block 20 by the operation of the drive unit 200. At this time. The cam 111 is formed to be concave on the side of the cam plate 110, the center portion is composed of the upper portion (111a) located on the upper side, both sides of the lower portion 111b is lower than the center. The pivoting arm 120 is rotatably mounted on the end block 20 at an upper end thereof, and the cam pin 121 is provided at one end thereof, and a connecting pin 122 connected to the flap B is provided at the other end thereof. Is provided, when the pivot arm 120 is rotated about the upper end by the cam pin 121, the flap (B) is rotated in the front and rear direction by the connecting pin 122, it is configured to open and close the vent. Therefore, as shown in FIG. 6A, when the cam plate 110 is positioned at the center portion, the cam pin 121 is positioned at the upper portion 111a of the cam 111 so that the pivot arm is positioned. When the flap B is rotated backward by the 120 to open the vent hole 11, and the cam plate 110 is moved forward or backward, as shown in (b) and (c) of FIG. Since the cam pin 121 is located at the downward portions 111b of both sides of the cam 111, the flap B is rotated forward by the pivot arm 120 to close the vent hole 11. That is, the vent hole 11 is opened only when the cam plate 110 is positioned at the center portion, and the vent hole 11 is closed when the cam plate 110 is moved forward or backward.

The drive unit 200 has an end portion of the indoor heat-expandable part 220 which is installed at both ends of the end block 20 of the main body A so as to be exposed to the front of the end block 20 and is stretched according to the indoor temperature. And, the end is provided so as to be exposed to the rear of the main body (A) is provided with an outdoor side thermal expansion and contracting unit 230 is stretched in accordance with the outdoor temperature.

As shown in FIG. 7, the driving unit 200 is fixedly installed at the end block 20 so that both ends are exposed to the front and rear of the end block 20, and both ends are formed with openings 211 facing both indoors and outdoors. The case 210, the indoor heat-expandable part 220 installed inside the rear of the case 210, the first transfer block 224 connected to the front of the indoor heat-expanded part 220, and the first 1 is provided in the outdoor thermal expansion and contraction unit 230 provided in the transfer block 224, the second transfer block 234 provided in the outdoor thermal expansion and contraction unit 230, and the second transfer block 234. And extends to the outside of the case 210 and includes a connection bar 240 connected to the cam plate 110. In addition, the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 are bimetals 222 and 232 spirally wound inside the cylinders 221 and 231 configured to be elastically coupled by two cylinders slidably coupled to each other. ) And the openings 223 and 233 connected to the openings 211 are formed at the end portions of the cylinders 221 and 231, and the air outside the room is introduced into the cylinders 221 and 231 through the openings 211, 223 and 233. It is configured to be introduced. At this time, the opening 233 of the outdoor thermal expansion and contraction unit 230 is connected to the opening 211 of the case 210 through the flexible connecting pipe 231a, and the bimetals 222 and 232 extend when the temperature rises. It is configured to be. Therefore, when the indoor and outdoor temperatures are equally cold, as shown in FIG. 7A, both the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 are reduced, and thus, the connection bar. 240 is located at the center. Then, as the temperature of the indoor side increases, as shown in FIG. 7B, the indoor thermal expansion and contracting unit 220 is extended, and thus, the first transfer block 224 and the outdoor thermal expansion and contraction unit 230. And the second transfer block 234 are both moved to the outside, so that the connection bar 240 is moved to the left. And, when the outdoor temperature rises, as shown in (c) of FIG. 7, as the outdoor thermal expansion and contraction unit 230 is extended, the second transfer block 234 is moved to the indoor side, and thus the connection bar. 240 is located at the center. And, when the indoor and outdoor temperature is lowered, the opposite action occurs. That is, when the indoor and outdoor temperatures are the same, the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 are expanded and contracted in the same manner, and the connection bar 240 is positioned at the center, and the indoor and outdoor temperatures are When different from each other, the connecting bar 240 is moved to a lower temperature, the cam plate 110 connected to the connecting bar 240 is moved forward and backward. In this way, as the cam plate 110 of the connecting unit 100 is moved back and forth, the cam arm 121 is lifted by the cam 111 of the cam plate 110 and the pivot arm 120 is rotated accordingly. The flap (B) rotates automatically in the front and rear direction to open and close the vent hole (11). That is, when the indoor and outdoor temperatures are the same, the cam plate 110 is positioned at the center, so that the flap B automatically opens the vent hole 11, and when the indoor and outdoor temperatures are different, the cam plate 110 is While sliding forward or backward, the flap B is rotated in a direction in which the vent hole 11 is closed, and when the temperature difference is very severe, the vent hole 11 is closed by the flap B.

In the natural ventilation device configured as described above, when the indoor and outdoor temperatures are equal to each other, as shown in FIG. 6A, the flap b is retracted to open the air vent 11 to ventilate the indoor air. When the indoor and outdoor temperatures are different from each other, as shown in FIGS. 6B and 6C, the flap B is automatically advanced to stop the ventilation by closing the air vent 11. Therefore, there is an advantage that can prevent the heating cost to rise. At this time, the temperature difference between the inside and the outside where the flap B is advanced back and forth has an advantage that can be freely set by adjusting the shape of the cam 111.

In the present embodiment, the drive unit 200 is illustrated that the case 210 is provided, but if necessary, it is possible to delete the configuration of the case 210.

In addition, although the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 have bimetals 222 and 232 inside the cylinders 221 and 231, they can be expanded and contracted according to temperature. It is also possible to expose the bimetals 222 and 232 to the outside without using the 221 and 231, and in addition to the bimetals 222 and 232 inside the cylinders 221 and 231, such as shape memory elements, gases or liquids. In accordance with the expansion and contraction, it is also possible to install or inject other kinds of objects so that the cylinders 221 and 231 expand and contract according to the heat.

In addition, the driving unit 200 is fixed to the end block 20 so that both ends are exposed to the front and rear of the end block 20, as shown in Figure 8 and both ends of the opening 211 toward the indoor and outdoor And a case 210 having an inner side, an inner side thermal expansion and contraction unit 220, an outer side thermal expansion and contraction unit 230, and the inner side thermal expansion and contraction unit 220 installed at the front and rear of the case 210, respectively. A pinion gear 250 having a connection bar 240 positioned between an outdoor side thermal expansion and contraction unit 230 and extending to an outside of the case 210 and connected to the cam plate 110, and the indoor unit; Each of the side thermal expansion and contraction parts 220 and the outdoor thermal expansion and contraction part 230 may be configured as a pair of rack gears 250 which are respectively coupled to opposite sides of the circumferential surface of the pinion gear 250. At this time, the configuration of the case 210, the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 is the same as the configuration of the first embodiment of the drive unit 200. Accordingly, the rack gear 250 is moved forward and backward with each other according to the expansion and contraction of the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230, and the pinion gear 250 is rotated and moved forward and backward. While the connecting bar 240 provided in the pinion gear 250 is also moved forward and backward, the cam plate 110 connected to the connecting bar 240 is moved forward and backward.

In addition, the driving unit 200 is fixed to the end block 20 so that both ends are exposed to the front and rear of the end block 20, as shown in Figure 9, both ends of the opening 211 toward the indoor and outdoor And a case 210 having an inner side, an inner side thermal expansion and contraction unit 220, an outer side thermal expansion and contraction unit 230, and the inner side thermal expansion and contraction unit 220 installed at the front and rear of the case 210, respectively. The slide block 260 is located between the outdoor thermal expansion and contraction unit 230, one side is provided with a connection bar 240 extending to the outside of the case 210 and connected to the cam plate 110, the slide Compression springs 226 and 236 are provided between the block 260 and the indoor and external thermal expansion and contracting units 220 and 230. At this time, when the indoor thermal expansion and contraction unit 220 and the outdoor thermal expansion and contraction unit 230 are expanded and contracted according to the indoor and outdoor air temperature, the compression springs 226 and 236 are properly compressed and the slide block 260 is heated internally. The cam plate 110 connected to the connecting bar 240 and the connecting bar 240 provided in the slide block 260 is moved forward and backward so as to be positioned at the center of the adjacent end of the elastic part 220 and the outdoor thermal elastic part 230. This is advanced back and forth.

As such, the configuration of the drive unit 200 can be changed as necessary.

And in the present embodiment. The cam 111 is composed of an upper portion 111a protruding upward from the center portion, and both sides are formed of a downward portion 111b lowered relative to the center portion thereof, when the cam plate 110 is moved forward or backward from the center. Flap (B) to close the vent hole 11, but as shown in Figure 10, one end is configured to be up and the other end is downward, when the cam plate 110 is moved to either of the front and rear automatically It is also possible to allow the vent 11 to close when the pore 11 is opened and moved to the other side.

In addition, although the connection unit 100 and the driving unit 200 has been illustrated in the end block 20 of the main body (A), if necessary, the connection unit 100 and the driving unit 200 is It is also possible to provide at both ends of the vent 10 of the main body A.

11 to 13 illustrate another embodiment according to the present invention. The main body A is connected to the connection unit 100 and extends in front of the main body A so that the user manually sets the flap. It is further provided with a control lever 300 that can operate B). At this time, the pivot arm 120 is connected to the spring 123, and elastically pressurized to rotate in the direction of opening the vent hole 11, the cam 111 is configured in the form of the lower surface is open When the cam plate 110 is moved forward and backward, only the upper surface of the cam pin 121 is pressed, so that the pivot arm 120 and the flap B rotate in the direction of closing the vent.

In addition, the operation lever 300 has a coupling hole 310 rotatably fitted to the outside of the connection unit 100 is formed in the center portion, the front end portion is extended to the front of the main body (A), and at the same time The long hole 320 is inserted into the cam pin 121 is formed. At this time, the long hole 320 is formed longer than the diameter of the cam pin 121, it is configured so that the play between the operation lever 300 and the pivot arm 120 can be generated. Therefore, when the user grasps the front end of the operation lever 300 and rotates in the vertical direction, the rotation arm 120 and the flap B are rotated by the cam pin 121 inserted into the long hole 320. At this time, between the operation lever 300 and the end block 20, the projections 330 and the recessed grooves 22 are formed, respectively, the user pushes the operation lever 300 to the upper flap (B) through When the pores 11 are closed, the protrusions 330 and the concave grooves 22 are coupled to each other to fix the operation lever 300 so as not to move.

In the natural ventilation device configured as described above, as shown in FIG. 11, the flap B closes the vent hole 11 by the operation lever 300 when the operation lever 300 is completely raised. At this time, the operation lever 300 is fixed to the position by the projection 330 and the recessed groove (22). Then, when the user pushes the front end of the operation lever 300 downward and rotates the operation lever 300 downward, as shown in Fig. 13 (a), the projection 330 and the concave groove 22 Is released, at this time, as shown in (b) of FIG. 13, by the spring 123, the cam pin 121 of the pivot arm 120 is caught by the cam 111 120 and the flap B are rotated to open the vent 11. Then, when the drive unit 200 slides the cam plate 110 in the front-rear direction according to the temperature difference between the indoor and the outside, as shown in (c) of FIG. 13, the action of the cam 111 and the cam pin 121. The rotating arm 120 and the flap (B) is rotated by, opening and closing the vent hole (11).

Therefore, the user can operate the operation lever 300 to completely close the vent hole 11, there is an advantage that the use is more convenient.

At this time, the spring 123 is connected to the flap (B) in addition to the rotation arm 120, it is also possible to allow the flap (B) to rotate elastically in the direction of opening the vent hole (11).

In addition, the natural ventilation device is configured to allow the user to adjust the ventilation hole 11 to be completely closed by using the operation lever 300, but if the configuration of the operation lever 300 is omitted, the above-described natural As in the first embodiment of the ventilation device, the vent hole 11 is opened and closed only by the cam plate 110.

In addition, as shown in FIG. 14, when the upper cam 112 in the front-rear direction is further formed on the upper portion of the cam 111, when the user pushes the operation lever 300 completely downward, the cam pin 121. ) Is inserted into the upper cam 111 beyond the boundary between the cam 111 and the upper cam 111, so that the flap B is fully retracted to fix the vent hole 11 in an open state. It is also possible. At this time, the portion where the cam pin 121 is formed in the pivoting arm 120 is to be bent elastically, so that the cam pin 121 rides over the boundary between the cam 111 and the upper cam 111. It is preferable to construct.

In addition, as shown in FIG. 15, the cam 111 is configured to have an upper portion 111a and a lower portion 111b as in the first embodiment, and an upper portion of the cam 111 is disposed above and below the cam 111. The cam 111 and the lower cam 113 are formed, so that the user uses the operation lever 300 so that the cam pin 121 is connected to the lower cam 113, the cam 111, and the upper cam 111. By being inserted into each, the flap (B) maintains a state in which the vent hole 11 is completely closed, or the flap (B) is automatically rotated by the temperature difference indoors and outside to adjust the opening and closing degree of the vent hole (11), It is also possible to be able to choose to keep the vent 11 fully open. In this case, the spring 123 connected to the pivot arm 120 or the flap B can be removed. In addition, in addition to the rotatable coupling to the end block 20, the operation lever 300 may be integrally fixed to one side of the pivot arm 120.

16 and 17 show another embodiment according to the present invention, wherein the coupling unit 100 is provided with a clutch mechanism 126, and the user operates the clutch mechanism 126 to drive the drive. It is configured to transmit or release the driving force of the unit 200 to the flap (B). To this end, the rotation arm 120 of the connection unit 100 is provided with a connection pin 122 and the operating lever 300 is integrally connected to one side is rotatably coupled to the end block 20 A first pivotal arm 124, and the pivotal arm 120 and the second pivotal arm 125, which is rotatably coupled on the concentric circle and provided with the cam pin 121 on one side, the first and second Rotating arms 124 and 125 are configured to be rotated separately from each other. At this time, the cam pin 121 of the second pivoting arm 125 is coupled to the cam 111 of the cam plate 110, the cam 111 when the cam plate 110 is advanced back and forth by the drive unit 200 cam 111 It rotates in the vertical direction by the projection, the protrusion 125a is formed in the circumference of the axis of rotation axis of the second pivot arm (125).

The clutch mechanism 126 is coupled to the first pivotal arm 124 so as to be moved forward and backward and has a fixed bar 126a which is coupled to the protrusion 125a of the second pivotal arm 125 when the forward portion is moved forward. When the user advances the fixing bar 126a, the tip of the fixing bar 126a is engaged with the protrusion 125a of the second pivotal arm 125 as shown in FIG. The first and second pivotal arms 125 are rotated integrally, and as shown in FIG. 17B, when the fixing bar 126a is retracted, the fixing bar 126a and the protrusion 125a The bond is released.

Accordingly, in the state where the fixing bar 126a of the clutch mechanism 126 is retracted to release the engagement of the first and second pivotal arms 125, the user operates the manipulation lever 300 to operate the first pivotal arm. By rotating 124, it is possible to manually adjust the degree of opening and closing of the vent hole 11 by the flap (B), by advancing the fixing bar (126a) of the clutch mechanism 126 first and first When the two rotation bars are coupled to each other, the first and second rotation arms 124 and 125 are automatically rotated by the action of the driving unit 200 and the cam plate 110, and the vent hole 11 is formed by the flap B. ) Can automatically adjust the degree of opening and closing.

Therefore, it can be controlled to adjust the opening and closing degree of the air vent 11 automatically or manually, there is an advantage that the use is more convenient.

The clutch mechanism 126 described in this embodiment shows an example of the clutch mechanism 126, and the structure of the clutch mechanism 126 can be freely changed.

18 illustrates another embodiment according to the present invention, wherein the driving unit 200 is operated by the air flow rate or wind speed circulated through the vent hole 11 to drive the connection unit 100. It is configured to be.

To this end, the driving unit 200 is provided in the inside of the body (A) and consists of a fan 270 connected to the connection unit (100).

At this time, the cam plate 110 of the connecting unit 100 is connected to the spring 114 for supporting the position of the cam plate 110 to be positioned on the upper portion (111a) of the cam 111, The rack gear 115 is provided at one side of the cam plate 110. In addition, the fan 270 is configured to rotate in opposite directions when air is introduced into the room from the outside, and when the air in the room exits to the outside, and a reducer 271 is provided on the rotating shaft of the fan 270. Is connected, the output shaft 271a of the reduction gear 271 is provided with a pinion gear 272 meshed with the rack gear 115, so that the driving force of the fan 270 can be amplified and transmitted to the pinion gear 272. It is composed.

Therefore, when the fan 270 is rotated by the wind passing through the vent hole 11, the driving force of the fan 270 is the cam plate 110 through the pinion gear 272 and the rack gear 115. When the driving force of the fan 270 is stronger than the elasticity of the spring 114, the cam plate 110 is moved forward and backward to rotate the flap (B) to open and close the vent hole 11, Only a certain level of air always passes through the vent 11 to allow constant ventilation.

The natural ventilation device configured as described above rotates the flap B by using the force of rotating the fan 270 by the flow rate and flow rate of the wind passing through the vent hole 11, and prevents excessive ventilation. Therefore, the noise is generated by the wind passing through the vent hole 11, there is an advantage that can prevent the heating and cooling costs rise.

In the present embodiment, the spring 114 is illustrated to be connected to the cam plate 110, but if necessary, it is also possible to connect to the pivot arm 120 or the flap (B) of the connection unit 100. . In this case, the spring 114 is installed to keep the flap B open to the maximum.

In addition, the structure of the connection unit 100 can be variously modified as in the modification of the first embodiment described above, and, if necessary, the operation lever 300 for manually operating the flap (B), It is also possible to further include the clutch mechanism 126.

1 is a side cross-sectional view showing a conventional natural ventilation device,

Figure 2 is a front view showing a conventional natural ventilation device,

Figure 3 is a side cross-sectional view showing a conventional natural ventilation device,

Figure 4 is a side cross-sectional view showing a natural ventilation device according to the present invention,

5 is an exploded view showing the operation mechanism of the natural ventilation device according to the present invention,

6 is a reference diagram for explaining the operation of the operation mechanism of the natural ventilation apparatus according to the present invention,

7 is a block diagram showing a driving unit of a natural ventilation device according to the present invention,

8 and 9 is a reference diagram showing another embodiment of the driving unit of the natural ventilation device according to the present invention,

10 is a reference diagram showing a modification of the cam of the operating mechanism of the natural ventilation apparatus according to the present invention,

11 is a configuration diagram showing a second embodiment of a natural ventilation device according to the present invention;

12 is an exploded view showing the operation mechanism of the natural ventilation device shown in FIG.

13 is a reference view for explaining the operation of the operating mechanism of the natural ventilation device shown in FIG.

14 and 15 is a reference diagram showing a modification of the cam of the natural ventilation device shown in FIG.

16 is a configuration diagram showing a third embodiment of the natural ventilation device according to the present invention;

17 is a reference view for explaining the operation of the natural ventilation device shown in FIG.

18 is a configuration diagram showing a fourth embodiment according to the present invention.

Claims (5)

A vent hole 11 penetrating the front and rear surfaces and embedded in the wall surface 1; A flap (B) provided inside the main body (A) to open and close the vent hole (11); In the natural ventilation device is provided in the main body (A) and includes an operating mechanism (C) for operating the flap (B) in the front-rear direction, the air outside the room can be ventilated, The operating mechanism (C) A connection unit (100) provided on the main body (A) and connected to the flap (B); An end portion is installed to be exposed to the front surface of the main body (A) and is stretched according to the indoor temperature. It includes a stretchable outdoor side expansion and contraction unit 230, the connection unit 100 is connected to the connection unit 100 by the expansion and contraction of the indoor heat expansion unit 220 and the outdoor heat expansion unit 230 Natural ventilation device comprising a drive unit (200) for operating. A vent hole 11 penetrating the front and rear surfaces and embedded in the wall surface 1; A flap (B) provided inside the main body (A) to open and close the vent hole (11); In the natural ventilation device is provided in the main body (A) and includes an operating mechanism (C) for operating the flap (B) in the front-rear direction, the air outside the room can be ventilated, The operating mechanism (C) A connection unit (100) provided on the main body (A) and connected to the flap (B); It is provided in the main body (A) and is connected to the connection unit 100 includes a fan 270 that is rotated by the flow rate or flow rate of the air ventilated through the vent (11) to operate the connection unit 100 Natural ventilation device comprising a. The cam plate according to claim 1 or 2, wherein the connection unit 100 is slidably mounted to the main body A in a forward and backward direction and connected to the drive unit 200, and a cam plate having a cam 111 formed on one side thereof. (110) and a cam pin (121) inserted into the cam (111) is provided with a natural ventilation device, characterized in that it comprises a rotating arm (120) connected to the flap (B). According to claim 1 or 2, the operation is connected to the connecting unit 100 or the flap (B) and extended to the front of the main body (A) to allow the user to manually operate the flap (B) Natural ventilation device further comprises a lever (300). According to claim 1 or 2, The connecting unit 100 is characterized in that the clutch mechanism 126 is provided with a selective transmission or release of the action of the drive unit 200 to the flap (B). Natural ventilation system.

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