KR20230138702A - Ventilation apparatus for building duct - Google Patents

Abstract

The disclosed content relates to a ventilation device for building ducts,
It is provided with a cylindrical body 10 installed in the duct hole ("d"), and extended edges 221 and 231 that are integrally formed with the body portion 21 and have several bolt holes 222 and 232. , From the inside of the expansion edges 221 and 231, an inclined surface portion 223, 232 is formed to form a cylindrical inner passage that gradually narrows from the upper to lower side toward the center, and two cap members 22 and 23 are formed. At least two first and second airflow forming members (31) as a cylindrical body forming overlapping vents (20) and pentagonal concave curves (32, 34) on the inner surface of the cylindrical body (10) on the center line. , (32) are connected to each other at the shoulder portion 35 to form a vortex with a twisted inclination in one direction within the cylindrical body 10, and an airflow guide member 30 is installed, and a duct hole ( A building duct including a first extension pipe (40) formed with a spiral portion (45) of an expanded diameter corresponding to the spiral portion (15) of the cylindrical body (10) so that it can be extended to fit the length of “d”). It is a ventilation device.

Description

Ventilation apparatus for building duct

The present invention is a ventilation device for building ducts for naturally ventilating the air discharged from the kitchen duct of a building. It's about.

In general, natural, rather than mandatory, ventilation devices for building ducts installed in the ducts of the hood system are installed in front of the ventilation duct (“d”) provided in the building, on the outside of the building wall, and are installed in accordance with the airflow outside. There is a ventilation hole (cap member) through which indoor airflow naturally escapes, and this ventilation hole covers the radial outside and has a structure to prevent rainwater flowing down the wall of the building from flowing in through the ventilation hole. Most of the buildings where these vents are installed have two or more floors, so in order to install these vents at a height of two or more floors, workers must climb up to the location where the vents are provided through a ladder or a separate support, and open the vents from the top of the ladder or support. Perform installation work outside the ball ("d"). Alternatively, where a kitchen hood is installed indoors, a cylindrical pipe is installed in a duct hole ("d") that is opened from the inside to the outside, and a ventilation hole is pre-assembled so that it penetrates the inside of the pipe and protrudes outward. It is also installed by passing through it and exposing it to the exterior wall (Registered Patent No. 10-0525297).

In this way, as a technology that allows the installation work of the ventilator of the ventilation system, which takes a long time outdoors, to be done indoors, Korean Patent Publication No. 10-0669027 describes a ductwork on the outer wall of the ductwork ("d") provided on the building wall. ("d") is inserted into a ventilation structure with long bolts fixed in it, and indoors, the indoor hood structure is assembled according to the bolt positions and assembled with nuts. However, the fire or exhaust devices of this ventilation system have a thickness of the outer wall of the building. , It is different for each villa, etc., so during construction, pipes appropriate for the thickness of the exterior wall must be cut into pieces and connected between the hood attached to the exterior wall and the indoor installation, which is cumbersome, resulting in longer work time and structural problems due to installation.

In addition, the hood cap, known as patent registration number 0525297 (registered on October 25, 2005), is a hood cap that can be safely installed indoors through a ventilation passage. It is a solid body that penetrates the inside and outside of a building and is installed on the ventilation passage of the building wall. A ventilation duct is installed in the air duct, the front end of which is bent and extended to form a ring-shaped edge, the front part that penetrates the ventilation duct and is exposed to the outside of the building has a predetermined airflow exhaust structure, and the rear end has a ring-shaped border so as to be caught by the ring-shaped edge. A ventilation system including a ventilation means forming a , is known to be installed so that the ventilation means penetrates the ventilation duct and is exposed on the outer wall of the building. However, after forming a hole in the wall indoors and inserting and fixing the ventilation duct from the inside, the ventilation means is coupled to the ventilation duct and fixed using a plurality of bolts, and a ventilation fan is installed at the rear. It is cumbersome to fix the ventilation duct to the hole, and the ventilation means combined with the cover and air flow guide must be fixed to the ventilation duct, making assembly difficult, or as a type of exhaust treatment device. , Ventilation systems consisting of a hood fan rotated by an electric motor and a tubular duct with a certain length are also known, and various forms are provided depending on the installation location and purpose.

The duct structure of the hood is largely composed of a cylindrical pipe or a flexible corrugated pipe, and the latter corrugated pipe-shaped duct structure is composed of a duct with a certain length communicating below the hood fan. However, the duct of the conventional hood as described above is flexible and is made in the form of a corrugated pipe, so it can be relatively freely moved and the length can be adjusted in a folded form. However, the duct is not sturdy and is prone to corrosion due to small scratches with long-term use. , Damage, etc. occurs, causing problems such as inability to perform the exhaust function. In addition, some of the conventional ducts have unsanitary problems such as stagnant water (polluted water) due to condensation generated when smoke and odor are discharged, or water mixed from the outside flows backwards in the opposite direction of the duct, and conventional hoods If the building duct ventilation device or exhaust system installed in the duct of the building is fixed, it is difficult to separate it after installation, so there is also a problem that it is difficult to separate it for sanitary cleanliness.

In addition to these problems, the most important problem is that the indoor airflow does not flow smoothly in the exhaust and building duct ventilation devices of these return and exhaust hood systems due to interference with external airflow.

Therefore, a ductwork ("d") building duct ventilation device that allows smooth natural ventilation of indoor airflow without mobilizing a forced ventilation structure and at the same time allows easy installation and construction of a building duct ventilation device installed in the duct of the hood system. It has been necessary.

(Document 1) Registered Patent No. 10-0525297 (announced on November 2, 2005) (Document 2) Registered Patent No. 10-0836822 (announced on June 12, 2008) (Document 3) Registered Patent No. 10-1580946 (announced on December 30, 2015) (Document 4) Utility model registration No. 0275281 (registered on April 30, 2002) (Document 5) Patent Registration No. 998224 (registered on November 29, 2010)

(Document 1) Publication Patent No. 10-2022-0029334 (published on March 8, 2022)

The present invention improves these problems with the building duct ventilation device of the conventional indoor airflow hood system, allowing for smooth discharge of indoor airflow, convenience during construction of the building duct ventilation device, and preventing airflow from occurring on the bottom of the main body of the building duct ventilation device. The purpose is to provide a ventilation device for building ducts of a hood system that prevents backflow of fluid.

The purpose of the present invention is to provide a ventilation device for building ducts to improve the flow of exhaust airflow.

The present invention seeks to provide a ventilation device for building ducts that allows airflow through a wide inlet portion within the main body of the ventilation device for building ducts to pass through a narrow neck portion and then be discharged to the wide outlet side in order to improve airflow.

The present invention seeks to provide a ventilation device for building ducts in which the flow of indoor air entering the ventilation device for building ducts forms a vortex and is discharged.

The purpose of the present invention is to improve the assemblyability of a ventilation device for building ducts that is assembled and installed in a duct hole (“d”).

The present invention seeks to provide a ventilation device for building ducts that blocks moisture flowing into the outlet side of the ventilation device for building ducts.

The present invention seeks to provide a ventilation device for building ducts that includes an extension means that can extend the length of the duct hole (“d”) when installing the ventilation device for building ducts.

In providing an assembly structure for a ventilation device for a building duct, the present invention provides a support member having a connection structure that matches the body diameter of the existing ventilation cap member when the diameter of the body portion does not match when assembling the ventilation cap member. It also has a purpose.

The ventilation device for building ducts of the present invention to achieve the above object is,

It is installed in the duct hole (“d”), the front end (11) is open, a water barrier (13) is formed at the rear end (12), and a gap maintaining piece (14) and a spiral portion (15) are formed on the outside. A cylindrical body (10) consisting of a cylindrical wall (16) of a predetermined length;

An inclined surface portion 223 that is formed integrally with the body portion 21 and has an expanded edge 221 forming a bolt hole 222, and forms an internal passage of the upper and lower beams from the inner side of the expanded edge 221 to the center. A second cap member 22 forming a , an inclined surface portion 233 having an expanded edge 231 formed with a bolt hole 232, and forming an internal passage of the upper and lower beams from the inner side of the expanded edge 231 to the center. ) forming the first cap member 23, the upper and lower ends of the expansion edge 221 through the support bolt 241 through the bolt holes 222 and 232 of the first and second cap members 22 and 23. A ventilation hole (20) made of a fastening member (24) made of a nut (242) fastened at;

It is a cylindrical body forming pentagonal convex curved surfaces 32 and 34 on the inner surface of the cylindrical body 10 on the center line, and the protruding curved surface 34 is fixed in close contact with the main surface of the cylindrical body 10, and each front , A jaw portion 35 is formed at the rear open end, and at least two or more first and second airflow forming members 31 and 32 are connected to each other at the jaw portion 35 and connected within the cylindrical body 10 to form a one-way An airflow guiding member (30) installed to form a vortex with a twisted inclination; and

A product forming a spiral portion 45 of an expanded diameter corresponding to the spiral portion 15 of the cylindrical body 10 so that it can be extended to match the length of the duct hole (“d”) at the outer rear end of the cylindrical body 10. This can be achieved as a ventilation device for building ducts including one extension pipe (40).

The ventilation device for building ducts of the present invention to achieve the above object is,

A cylindrical wall installed in the duct hole (“d”), having front and rear ends (11) and (12), a water barrier (13) formed at the rear end (12), and a gap maintaining piece (14) formed on the outside. A cylindrical body (10) forming (16) and having insertion grooves (16) formed at the front and rear ends (11) and (12);

An inclined surface portion 223 that is formed integrally with the body portion 21 and has an expanded edge 221 forming a bolt hole 222, and forms an internal passage of the upper and lower beams from the inner side of the expanded edge 221 to the center. A second cap member 22 forming a , an inclined surface portion 233 having an expanded edge 231 formed with a bolt hole 232, and forming an internal passage of the upper and lower beams from the inner side of the expanded edge 231 to the center. ) forming the first cap member 23, the upper and lower ends of the expansion edge 221 through the support bolt 241 through the bolt holes 222 and 232 of the first and second cap members 22 and 23. A ventilation hole (20) made of a fastening member (24) made of a nut (242) fastened at;

The body portion 21 of the ventilation hole 20 forms a circular body 73 with a diameter into which it is inserted, and forms a circular frame 71 with an expanded diameter that matches the size of the cylindrical body 10, along the lower edge. A number of insertion pins (72) are formed to be inserted into the insertion groove (18) of the cylindrical body (10), a locking groove (74) into which the locking piece (211) is inserted and caught is formed, and the airflow guide member (30) is formed. A support member 70 forming a horizontal expansion portion 75 forming a first blocking portion 75a eccentric to one side to correspond to the eccentric passage, and a relatively narrow second blocking portion 75b; and

A second extension pipe (50) having several insertion pieces (52) formed on the upper edge of the short-width circular frame (51); This can be achieved as a ventilation device for building ducts that includes.

The ventilation device for building ducts of the present invention to achieve the above object is,

As a circular plate, several locking pieces 62 can be formed along its edge, and the locking piece 62 extends inward at the rear edge as shown, and several locking grooves 46 are formed correspondingly. It can be achieved as a ventilation device for building ducts that further includes a cover member 60 that is assembled by rotating and locking the locking piece 62, and is detachable by releasing and rotating the locking piece 62.

As described above, the present invention improves the problems of the building duct ventilation device of the conventional indoor airflow hood system, and as the exhaust airflow forms a whirlwind path within the cylindrical body, the moving flow is accelerated to achieve a smooth airflow discharge effect. get

The present invention improves these problems with the building duct ventilation device of the conventional indoor airflow hood system, allowing for smooth discharge of indoor airflow, convenience during construction of the building duct ventilation device, and preventing airflow from occurring on the bottom of the main body of the building duct ventilation device. It is possible to provide a ventilation device for building ducts of a hood system that prevents backflow of fluid.

The present invention can provide a ventilation device for building ducts to improve the flow of exhaust airflow.

The present invention seeks to provide a ventilation device for building ducts that allows airflow through a wide inlet portion within the main body of the ventilation device for building ducts to pass through a narrow neck portion and then be discharged to the wide outlet side in order to improve airflow.

The present invention seeks to provide a ventilation device for building ducts in which the flow of indoor air entering the ventilation device for building ducts forms a vortex and is discharged.

The present invention improves the assembling of a ventilation device for building ducts that is assembled and installed in a duct hole (“d”).

The present invention provides a ventilation device for building ducts that blocks moisture flowing into the outlet side of the ventilation device for building ducts.

The present invention seeks to provide a ventilation device for building ducts that includes an extension means that can extend the length of the duct hole (“d”) when installing the ventilation device for building ducts.

In providing an assembly structure for a ventilation device for a building duct, the present invention provides a support member having a connection structure that matches the body diameter of the existing ventilation cap member when the diameter of the body portion does not match when assembling the ventilation cap member. .

In providing an assembly structure for a ventilation device for building ducts, the present invention provides a structure suitable for such a vortex formation path, so that the airflow can accelerate as the initially entering airflow passes through the vortex formation section.

A ventilation device for building ducts of a hood system is provided that prevents backflow of fluid that occurs at the bottom of the main body of the ventilation device for building ducts.

Figure 1 is a combined perspective view of a ventilation device for building ducts according to Example 1 of the present invention,
Figure 2 is an exploded perspective view of a ventilation device for building ducts according to Embodiment 1 of the present invention;
Figure 3 is an exploded perspective view showing the back of a ventilation device for building ducts according to Example 1 of the present invention;
Figure 4 is an exploded cross-sectional view of a ventilation device for building ducts according to Example 1 of the present invention;
Figure 5 is a cross-sectional view of the installation state of the ventilation device for building ducts according to Example 1 of the present invention;
Figure 6 is a schematic illustration illustrating the operation of the ventilation device for building ducts according to Example 1 of the present invention;
Figure 7 is an exploded perspective view of a ventilation device for building ducts according to Example 2 of the present invention, and Figure 8 is a bottom perspective view of a ventilation device for building ducts according to Example 2 of the present invention.
Figure 9 is an exploded cross-sectional view of a ventilation device for building ducts according to Example 2 of the present invention;
Figure 10 is a combined cross-sectional view of a ventilation device for building ducts according to Example 2 of the present invention.

Hereinafter, a ventilation device for building ducts according to a preferred embodiment of the present invention will be described in detail with the accompanying drawings.

<Example 1>

Among the attached drawings, Figure 1 is a combined perspective view of a ventilation device for building ducts according to Embodiment 1 of the present invention, Figure 2 is an exploded perspective view of a ventilation device for building ducts according to Embodiment 1 of the present invention, and Figure 3 is a combined perspective view of a ventilation device for building ducts according to Embodiment 1 of the present invention. It is an exploded perspective view showing the rear side of the ventilation device for building ducts according to Example 1, Figure 4 is an exploded cross-sectional view of the ventilation device for building ducts according to Example 1 of the present invention, and Figure 5 is an exploded cross-sectional view of the ventilation device for building ducts according to Example 1 of the present invention. It is a cross-sectional view of the installation state of the ventilation device for building ducts, and Figure 6 is a schematic illustration explaining the operation of the ventilation device for building ducts according to Embodiment 1 of the present invention.

The present invention according to the above drawings largely includes a cylindrical body 10 installed in a duct hole ("d"), a ventilation hole 20 exposed to the outside of the duct hole ("d") for discharging indoor airflow, and a cylindrical body An air flow guiding member (30) installed within (10) to increase the discharge force of the air flow, and a first extension pipe connected to extend the length of the cylindrical body (10) when it is shorter than the length of the duct hole ("d"). It consists of (40).

The cylindrical body 10 is installed in the duct hole (“d”) as shown in FIGS. 2, 4, and 5 of the accompanying drawings, the front end 11 is open, and the rear end 12 is an open end. A cylindrical wall (17) of a predetermined length is formed with a water barrier (13) on the lower side to prevent unnecessary backflow of water to the inside, and a gap maintenance piece (14) and a connecting spiral portion (15) are formed on the outside. It consists of If the inside of the duct hole (“d”) is narrow due to construction reasons, the gap maintenance piece (14) can be removed and installed, and a hanging hole (16) can be formed on the cylindrical wall (17).

As shown in FIGS. 2, 3, and 4, the ventilation hole 20 can be installed with various types of cap members. In the drawing, the ventilation hole 20 has two stages of caps, that is, the first cap member 22 and the second cap member 23. ) can be assembled as a support bolt 241 forming the fastening member 24 and a nut 242 coupled to the lower side of the support bolt 241. Alternatively, it can be performed with just one of the first and second cap members 22 and 23.

The ventilation port 20 applied to the ventilation device of this embodiment has a structure in which two-stage cap members 22 and 23 are overlapped, and its lower body portion 21 is inserted and installed into the distal end 11 of the cylindrical body 10. A locking piece 211 may be formed as much as possible.

The first cap member 22 and the second cap member 23 may commonly form a body portion 21 to be inserted and installed from the outside of the duct hole (“d”).

The first cap member 22 is formed integrally with the body portion 21 and has an expanded edge 221 formed with several bolt holes 222, and gradually moves upward and downward from the inside of the expanded edge 221 to the center. It is possible to form an inclined surface portion 223 that forms a narrow, cylindrical internal passage.

The second cap member 23 may form a body, not shown, and has an expanded edge 231 formed integrally with the body and having several bolt holes 232, and the expanded edge 231 It is possible to form an inclined surface portion 233 that forms a cylindrical internal passage that gradually narrows from the inner side to the center toward the upper and lower sides.

The nut 242 penetrates the support bolt 241 from the outside of each of the bolt holes 222 and 232 of the first cap member 22 and the second cap member 23 and passes through the support bolt 241 at the bottom. It is possible to form a ventilation port 20 consisting of two stages by fastening as. The support bolt 241 and nut 242 may be referred to as a fastening member 24.

The airflow guide member 30 forms at least two stacked and assembled structures so that the airflow exhausted from the room creates a vortex that improves the internal airflow in order to minimize the loss of the exhaust flow due to turbulence and friction occurring outside. can do. The airflow guiding member 30 has two stacked and assembled structures, the first airflow guiding member 31 and the second airflow guiding member 32, as shown in the drawing, but may have two or more assembled structures as needed. The airflow guide member 30 forms several cylindrical bodies (pentagons in the drawing) forming 3-6 hexagonal concave curved portions 32 and 34 on the inner surface of the cylindrical body 10 on the center line, thereby forming the cylindrical body (10). 10) The protruding curved surface 34 is in close contact with the inner main surface and can be fixed. The airflow guide member 30 is made by stacking and assembling two pieces as shown in the drawing, so that the concave curved portions 32 and 34 on the entire inner peripheral surface can form a twisted shape with an inclination in one direction.

This airflow guide member 30 forms a chin portion 35 at each of the front and rear open ends (symbols omitted), so that two or more first and second airflow forming members 31 and 32 are connected to the chin portion 35. You can access and extend from .

Therefore, a torsional airflow can be formed within the cylindrical body 10. As is known, the flow of gas and fluid flowing along the twisted concave curved portions 33 and 34 is discharged toward the central outlet of the ventilation port 20 to form a vortex (twisting group, fluid turbulence), and By forming an airflow proportional to the flow of external airflow (Bernoulli's theorem), an airflow discharge effect with rapid discharge power can be obtained. It is known that the discharge power proportional to the flow of the external air current of the ventilation opening 20 has a significant discharge power even in a duct hole in which nothing is formed. In particular, it is known that the discharge force by the airflow guide member 30 of the present invention has a faster discharge force as it forms a vortex. In other words, by forming the air flow guiding member 30 that forms a vortex within the cylindrical body 10, the speed of the vortex is increased to a degree that overcomes the obstruction caused by the turbulent friction on the outside of the ventilation hole 20, thereby preventing external airflow. It is also known that it can overcome the resistance of countercurrent gas.

Therefore, in addition to the airflow proportional to the external airflow through the ventilation hole 20 (according to Bernoulli's theorem), a vortex flow is added to achieve a more rapid discharge effect.

The first extension pipe 40 forms a spiral portion 45 with an expanded diameter corresponding to the spiral portion 15 of the cylindrical body 10, and an insertion groove 41 can be formed at the rear opened inner edge. there is.

Therefore, if the length of the duct hole (“d”) is longer than the normal length, the length of the cylindrical body 10 is shortened and can be extended. That is, the spiral portion 45 corresponding to the spiral portion 15 can be extended by screw fitting to fit the length of the duct hole (“d”).

The ventilation device for building ducts of Example 1 of the present invention constructed as described above has an airflow guiding member 30 installed on the inner peripheral surface of the cylindrical body 10 toward the front of the inside of the cylindrical body 10, as shown in FIGS. 5 and 6 of the accompanying drawings. In a state in which at least two stages of air flow guide members 30 are connected to form concave curved portions 32 and 34 that are twisted within the cylindrical body 10 by connecting the jaw portions 35 and 36 so as to contact each other. A ventilation hole (20) is inserted into the front end of the cylindrical body (10), and if necessary, the first extension pipe (40) is installed at the rear end of the cylindrical body (10) according to the length of the duct hole (“d”).

In this way, the airflow exhausted from the room through the airflow guide member 30 forms a twist (vortex) proportional to the indoor airflow in the vortex formation section ("a"), and at the same time, the external airflow according to Bernoulli's theorem of the ventilation opening 20 is formed. A strong increase in proportion to the flow occurs in the airflow increase section ("b"), forming a strong exhaust force, which can be discharged to the discharge section ("c"). Of course, external gas can create a strong wind and cause obstruction or reverse flow. However, compared to the conventional case where there is no vortex formation section (“a”), the countercurrent flow can be suppressed.

Therefore, the indoor airflow is discharged more easily with an increase in speed proportional to the external airflow through the ventilation opening 20. This exhaust condition is achieved by using the airflow guide member 30, compared to the conventional indoor exhaust force in the duct hole (“d”) according to the Bernoulli theorem of the ventilation port 20, which was dependent solely on the exhaust force according to the Bernoulli theorem of the ventilation port 20. Not only does it increase speed as a vortex through the air, but it is also discharged while minimizing loss due to external turbulence and friction, so the flow of indoor air is improved.

<Example 2>

Among the attached drawings, Figure 7 is an exploded perspective view of a ventilation device for building ducts according to Example 2 of the present invention, Figure 8 is a bottom perspective view of a ventilation device for building ducts according to Example 2 of the present invention, and Figure 9 is an embodiment of the present invention. This is an separated cross-sectional view of the ventilation device for building ducts according to Example 2, and Figure 10 is a combined cross-sectional view of the ventilation device for building ducts according to Example 2 of the present invention.

In explaining Example 2, parts that are consistent with the configuration of Example 1 will be explained by referring to the drawings of Example 1, and the different configurations will be described in detail below.

The ventilation device for building ducts of the present invention of Example 2 largely consists of a cylindrical body (10), a ventilation port (20), a second extension pipe body (50), a cover member (60), and a support member (70).

First, the cylindrical body 10 is installed in the duct hole (“d”), the front end 11 is open, the rear end 12 forms an open end, and a water barrier 13 is formed on the lower side to move inward. It is made up of a cylindrical wall (16) of a predetermined length, with a gap maintaining piece (14) formed on the outside to prevent unnecessary backflow of moisture. In the drawing, insertion grooves 16 may be formed in the front and rear ends 11 and 12 of the cylindrical body 10. When installing the cylindrical body 10 having the insertion groove 16, it can be extended to the second extension pipe 50, which will be described later, having the insertion piece 51 formed, and the support having the insertion piece 72 formed thereon. Assembly and installation of the ventilation port 20 may be possible with the member 70.

The ventilation hole 20 is a variety of cap members known by the present applicant. In the drawing, the ventilation hole 20 forms a two-stage expansion wing (hereinafter referred to as an expansion edge) and has a locking piece to be inserted and installed on the distal end 11 of the cylindrical body 10. A body portion 21 that forms (211) and is simultaneously inserted and installed from the outside of the duct hole (“d”), and an extended edge portion (221) formed integrally with the body portion (21) and forming several bolt holes (222). ), and a first cap member 22 formed with an inclined surface portion 223 to form a cylindrical inner passage that gradually narrows from the inside of the expansion edge 221 to the center toward the upper and lower ends, and this first cap member A support member 24 consisting of a support bolt 241 penetrating from the outside of the bolt hole 222 of (22) and a nut 242 fastened at the bottom of the support bolt 241, and this support member 24. The second cap member 23, which is installed above the first cap member 22 and forms an extended edge 231, a bolt hole 233, and an inclined surface 233, is assembled to form a two-stage cap member. do.

In particular, when installing the body part 21 of the ventilation hole 20 on the cylindrical body 10, if the body part 21 is small and does not fit the diameter of the tip 11 of the cylindrical body 10, it must be installed. The support member 70 may be added.

As shown in the drawing, the support member 70 forms a circular body 73 with a diameter into which the body portion 21 of the ventilation hole 20 is inserted, and has a shape below it that fits the size of the cylindrical body 10. A circular frame 71 with an expanded diameter may be formed, and several insertion pins 72 may be formed along the lower edge to be inserted into the insertion groove 18 of the cylindrical body 10. A locking groove 74 into which the locking piece 211 formed on the body portion 21 of the ventilation hole 20 is inserted can be formed in the tubular body 73 of the support member 70. In particular, in the support member 70 of this structure, the circular frame 71 is eccentric on one side to correspond to the eccentric passage of the airflow guide member 30 to correspond to the vortex forming structure of the airflow guide member 30, which will be described later. It is possible to form a horizontal expansion portion 75 that forms a first blocking portion 75a and a relatively narrow second blocking portion 75b. This horizontal expansion portion 75 is formed in the inner diameter direction of the cylindrical body 10. The portion of the airflow guide member 30 where the airflow does not move can be blocked.

The airflow guide member 30 is shaped like a cylinder with a certain length (width) and a central point so that the airflow exhausted from the room creates a vortex that improves the internal airflow in order to minimize the loss of the exhaust flow due to turbulence and friction occurring outside. Several cylindrical bodies (pentagons in the drawing) forming 3-6 hexagonal concave curved portions 32 and 34 are formed to contact the inner diameter of the main body 10, and several stacked assemblies are formed within the cylindrical body 10 (as shown in the drawing). 2), the entire inner peripheral surface forms a twisted shape in which the concave curved portions 32 and 34 have an inclination in a certain direction, and the jaw portions 35 and 36 are located on each of the front and rear open ends 31 and 33. ), and at least two or more are connected to each other to form a vortex flow by the twisted concave curved portions 32 and 34 within the cylindrical body 10. It is known that by connecting at least two units in series within the cylindrical body 10, the speed of the indoor airflow can be increased enough to overcome the interference caused by external turbulent friction.

The second extension pipe 50 is an extension pipe connected to extend the cylindrical body 10 when the length is shorter than the length of the construction duct hole ("d"),

Several insertion pieces 52 can be formed on the upper edge of the short-width circular frame 51, and a water barrier 53 can be formed on the lower edge. Alternatively, the water barrier 13 of the cylindrical body 10 may be removed and the water barrier 53 may be installed on the second extension pipe 50. In this Embodiment 2, it is shown in the drawing, but can be omitted.

As shown in FIG. 8, the cover member 60 is installed at the rear end of the cylindrical body 10 or the first and second extension pipes ( 40) The rear end of (50) can be temporarily blocked with a cover member (60) to prevent foreign substances from entering the interior, moisture erosion, etc.

The cover member 60 is a circular plate that can form several locking pieces 62 along its edges, and the locking pieces 62 extend inward at the rear edge as shown to form a locking groove 46. Correspondingly, several pieces are formed, assembled by rotation and locking of the locking piece 62, and released and separated by annual rotation. Likewise, if the water barrier 13 of the cylindrical body 10 is omitted, a water barrier 43 that blocks moisture flowing back inside can be formed.

In this way, the airflow exhausted from the room through the airflow guide member 30 forms a twist (vortex) proportional to the indoor airflow in the vortex formation section (“a”) as shown in FIG. 10ㅇ-, and at the same time, )'s Bernoulli's theorem, a strong increase in speed proportional to the flow of the external air current occurs in the air flow increase speed section ("b"), forming a strong exhaust force, and can be discharged into the discharge section ("c"). Of course, the external gas can be discharged to the discharge section ("c"). Strong winds may cause obstruction or reverse flow, but the reverse flow can be suppressed compared to the conventional case where there is no vortex formation section (“a”).

Therefore, the indoor airflow is discharged more easily with an increase in speed proportional to the external airflow through the ventilation opening 20. This exhaust condition is achieved by using the airflow guide member 30, compared to the conventional indoor exhaust force in the duct hole (“d”) according to the Bernoulli theorem of the ventilation port 20, which was dependent solely on the exhaust force according to the Bernoulli theorem of the ventilation port 20. Not only does it increase speed as a vortex through the air, but it is also discharged while minimizing loss due to external turbulence and friction, so the flow of indoor air is improved.

The ventilation device for building ducts of Example 2 of the present invention constructed as described above,

First, since the cylindrical body 10 is a cylindrical tube with open front and rear ends, several insertion grooves 103 are formed on the inside at the front and rear ends to fit the diameter of the body 21 of the vent 20 that does not match the size of the front. The support member 70 is extended and installed to fit, and if the diameter of the body part 21 of the ventilation hole 20 matches, it is inserted as is, and the insertion piece 72 is inserted into the front end of the cylindrical body 10. Make sure it is supported.

Thereafter, front and rear open ends 31 ( At least two of the jaw portions 35 and 36 formed in 33) are connected to each other to form twisted concave curved portions 32 and 34 within the cylindrical body 10.

This airflow guide member 30 moves while creating a vortex in the twisted concave curved portions 32 and 34 with an inclination angle to be exhausted from the room, and is exhausted by the external airflow without any special power through the ventilation hole 20. will be.

At this time, the exhaust flow generated from the ventilation port 20 is exhausted according to Bernoulli's theorem and at the same time, it twists in one direction inclined along the concave curved portions 32 and 34 and forms a vortex, so the air flow speed increases and external turbulence occurs. Since it is exhausted while minimizing losses due to friction, it improves the flow of indoor air. It is already known that the effect of increasing the speed of air flow due to such vortices (vortices) increases the speed enough to overcome the interference caused by external turbulence and friction.

On the other hand, as is known from many literature, the pressure at the center of a vortex, eddy, or whirlpool can be interpreted as low and the pressure gradually increases as the distance from the center increases, and it can be very useful in low pressure applications such as ventilation devices. Another role of the vortex is to mix the air well, and because laminar flow is good, aero devices are added to create laminar flow. Laminar flow is advantageous because air resistance is small. However, it is difficult to maintain laminar flow, and in most situations, turbulent and vortex flows are often more advantageous than laminar flow.

Additionally, it is known that all fluids tend to move in the form of spirals or vortics when moving under the influence of natural forces. Typically, these turns or vortices follow a mathematical sequence known as the Golden Ratio or Fibonacci-like Progression.

In most cases, the cylinders that guide normal air currents to convey fluid flow by allowing the fluid to naturally flow in its proper path increase the inefficiencies created by turbulence and friction. Conventionally developed technologies rarely follow the properties of natural fluid flow.

Most of the known fluid flow regulators are usually designed according to the Golden Ratio or Golden Section, or are designed such that the amount of fluid flowing through the flow regulator expands or contracts according to the Golden Ratio or Golden Section.

Therefore, the air flow guide member 30 of Examples 1 and 2 described above has a pivot shape and provides a fluid passage that at least most of the time follows the characteristics of the golden ratio or golden section. Figure 1 is a drawing of a spiral curve following the golden ratio or golden section, showing the characteristics of the golden section. When unfolding a spiral, the rule that the radius of the curve increases as measured by the equiangular radii (e.g., E, F, G, H, I, J) is constant. This can be represented by a triangle that satisfies the equation a:b=b:a+b, satisfies a ratio of approximately 1:0.168, and is represented by successive angular radii maintained throughout the curve.

The curvature of the surface of each airflow guide member, which controls the airflow, is two-dimensional or three-dimensional, corresponding to the lines of vorticity or streak lines found in naturally occurring vortices. It means having a shape. In general, if the surface curvature generally follows the characteristics of the golden ratio or golden section, the change in cross-sectional area of the airflow guide member also generally follows the golden ratio or golden section.

In some airflow guiding elements the curvature of the active surface follows a conformal helix. Additionally, this characteristic of the golden ratio or golden section is found in nature in the shape of the interior or exterior of the shells of polypods and cephalopods of the mollusk phylum. A common feature of at least some of the present embodiments is that the fluid passageway formed by the flow control device generally corresponds to the interior or exterior shape of the shell of one or more species of the gastropods and cephalopods of the mollusk phylum.

If a fluid is directed to flow through a passage with a curvature roughly following the Golden Ratio or Golden Section, the fluid flow over the surface becomes approximately non-turbulent, which tends to reduce cavitate. As a result, fluid flow over the surface is more efficient than occurs in the prior art where the passage does not generally follow the golden section. As a result of the reduction in the occurrence of turbulence in the fluid passing through such passages, the air flow according to the air flow guide member applied to the present invention allows the fluid to flow with greater efficiency than that of a conventional air flow guide member with equivalent dimensional characteristics.

It is obvious that it is impossible to represent the features of the embodiments in simple two-dimensional drawings. To aid the reader's understanding of the present embodiments, the external surfaces of the embodiments are depicted in the drawings in such a way that they correspond to the internal surfaces. As a result, the walls of the embodiments have a constant thickness. In this way, the concept of an inner helical/spiral shape is achieved. For practical fluid flow control devices, the configuration of the exterior surface is not critical. Therefore, the inner surface can maintain a complex shape as shown in the drawings, while the outer surface can be formed in a simple shape such as a cone shape.

10: cylindrical body, 11: front end, 12: rear end, 13: water stopper, 14: gap maintenance piece, 15: spiral part, 16: hanging hole, 17: cylindrical wall, 20: ventilation hole, 21: body part, 22 : first cap member, 221: expansion edge, 223: inclined surface portion, 23: second cap member, 231: expansion edge, 233: inclined surface portion, 24: fastening member, 241: support bolt, 242: nut, 30: airflow Guide member, 31, 32: first and second air flow guide members, 32: concave curved surface, 34: protruding curved surface, 35: shoulder part, 40: first extension pipe body, 45: spiral part, 46: locking groove, 50: first 2 extension pipe body, 51: frame body, 52: insertion piece, 60: cover member, 62: lock piece, 70: support member, 71: circular frame body, 72: insertion piece, 73: body, 74: locking groove, 75 : horizontal expansion part, 75a: first blocking part, 75b: second blocking part,

Claims (3)

In a ventilation device for building ducts,
It is installed in the duct hole (“d”), the front end (11) is open, a water barrier (13) is formed at the rear end (12), and a gap maintaining piece (14) and a spiral portion (15) are formed on the outside. A cylindrical body (10) consisting of a cylindrical wall (16) of a predetermined length;
An inclined surface portion 223 that is formed integrally with the body portion 21 and has an expanded edge 221 forming a bolt hole 222, and forms an internal passage of the upper and lower beams from the inner side of the expanded edge 221 to the center. A second cap member 22 forming a , an inclined surface portion 233 having an expanded edge 231 formed with a bolt hole 232, and forming an internal passage of the upper and lower beams from the inner side of the expanded edge 231 to the center. ) forming the first cap member 23, the upper and lower ends of the expansion edge 221 through the support bolt 241 through the bolt holes 222 and 232 of the first and second cap members 22 and 23. A ventilation hole (20) made of a fastening member (24) made of a nut (242) fastened at;
It is a cylindrical body forming pentagonal convex curved surfaces 32 and 34 on the inner surface of the cylindrical body 10 on the center line, and the protruding curved surface 34 is fixed in close contact with the main surface of the cylindrical body 10, and each front , A jaw portion 35 is formed at the rear open end, and at least two or more first and second airflow forming members 31 and 32 are connected to each other at the jaw portion 35 and connected within the cylindrical body 10 to form a one-way An airflow guiding member (30) installed to form a vortex with a twisted inclination; and
A product forming a spiral portion 45 of an expanded diameter corresponding to the spiral portion 15 of the cylindrical body 10 so that it can be extended to match the length of the duct hole (“d”) at the outer rear end of the cylindrical body 10. 1 extension pipe (40);
Ventilation device for building ducts including. In a ventilation device for building ducts,
A cylindrical wall installed in the duct hole (“d”), having front and rear ends (11) and (12), a water barrier (13) formed at the rear end (12), and a gap maintaining piece (14) formed on the outside. A cylindrical body (10) forming (16) and having insertion grooves (16) formed at the front and rear ends (11) and (12);
An inclined surface portion 223 that is formed integrally with the body portion 21 and has an expanded edge 221 forming a bolt hole 222, and forms an internal passage of the upper and lower beams from the inner side of the expanded edge 221 to the center. A second cap member 22 forming a , an inclined surface portion 233 having an expanded edge 231 formed with a bolt hole 232, and forming an internal passage of the upper and lower beams from the inner side of the expanded edge 231 to the center. ) forming the first cap member 23, the upper and lower ends of the expansion edge 221 through the support bolt 241 through the bolt holes 222 and 232 of the first and second cap members 22 and 23. A ventilation hole (20) made of a fastening member (24) made of a nut (242) fastened at;
The body portion 21 of the ventilation hole 20 forms a circular body 73 with a diameter into which it is inserted, and forms a circular frame 71 with an expanded diameter that matches the size of the cylindrical body 10, along the lower edge. A number of insertion pins (72) are formed to be inserted into the insertion groove (18) of the cylindrical body (10), a locking groove (74) into which the locking piece (211) is inserted and caught is formed, and the airflow guide member (30) is formed. A support member 70 forming a horizontal expansion portion 75 forming a first blocking portion 75a eccentric to one side to correspond to the eccentric passage, and a relatively narrow second blocking portion 75b; and
A second extension pipe (50) having several insertion pieces (52) formed on the upper edge of the short-width circular frame (51);
Ventilation device for building ducts including. According to claim 1 or 2,
As a circular plate, several locking pieces 62 can be formed along its edge, and the locking piece 62 extends inward at the rear edge as shown, and several locking grooves 46 are formed correspondingly. A cover member (60) that is assembled by rotating and locking the locking piece (62) and is detachable by releasing and rotating the locking piece (62);
A ventilation device for building ducts further comprising a.