KR101865613B1 - Indoor ventilation device for using the air exhaust - Google Patents

Abstract

A ventilation device having a non-powered natural exhaust structure for exhausting an indoor airflow as an air flow of the outside air, the inlet and outlet spacing (a) being adjustable to a longitudinal axis on the central axis. This ventilating apparatus comprises an outer cover member (20) having a center axis long axis (21) downwardly formed at an inner central portion of a circular plate body, an outer cover member (20) having a circular plate - like upper surface, A slope surface 32 inclined downward at a predetermined angle, a horizontal surface 34 and a wall surface 35 are formed in the exhaust passage 31 at predetermined intervals and a fastening hole 33 is formed A ventilation device using a non-powered external air in which an indoor airflow is naturally exhausted by the intensity of an outside air as an outside air guide member (30) coupled with an outer cover member (20) And a plurality of through holes 42 are formed in the center of the insulator 40. The center portion of the insulator 40 forms a shaft hole 43 through which the long shaft 21 is inserted and coupled, Assembled with the outside air guide member 30 and the insectproof plate member 40 sandwiched therebetween, The through hole 33 of the outside air guide member 30 and the through hole 44 of the outside air guide member 30 constitute the cylindrical wall portion 11 which forms the cylindrical wall portion 11 which forms the cylindrical wall portion 11 and which forms the fastening hole 13 at a predetermined position of the enlarged surface portion 12, And the length of the long shaft 21 screwed into the shaft hole 43 is adjusted so that the gap a between the inlet and the outlet is adjusted, Thereby providing an exhaust device.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an indoor air-

The present invention relates to a non-powered indoor air flow discharging device for discharging an indoor air flow by an outside wind of a building, which prevents air from flowing back from the outside to the inside, thereby enabling efficient ventilation, The present invention relates to a non-powered indoor air exhaust system capable of adjusting the clearance area of the air inlet and outlet so as to be matched with the high-rise, low-rise, or highland of the building in proportion to the wind intensity applied to the outer wall.

Background Art [0002] Ventilation ducts, hood caps, ventilation ducts for ducts, range hood exhaust units, and air supply and exhaust hoods (hereinafter, referred to as non-powered indoor air flow exhaust units) are known in the exhaust ducts of buildings for discharging smoke such as indoor air and range hoods In addition, there is also known a stationary ventilator with a chimney as a ventilator. These are composed of a wide mouth, an outlet, and a neck of narrow width which pass through as a strength of wind in a building or a roof, Ventilation devices of a substantially T-shaped venturi type are known.

Particularly, the non-powered indoor air flow exhaust devices, which are described below through the present inventor and proposed and registered through the accompanying drawings, FIGS. 1A, 1B and 1C, are also such non-powered indoor air flow exhaust devices.

First, the ventilator shown in Fig. 1A is a cylinder passing through the inside and the outside of the building, which is installed on the ventilation passage of the building wall and has a ring-shaped edge formed by bending the front end of the ventilation tube, And a ventilation means having a predetermined air flow exhaust structure for the front portion to be exposed from the outside and a ring-shaped rim for the rear end portion to be caught by the ring-shaped edge portion has been proposed.

1B has a trapezoidal cross section having a narrow upper part and a wide inclined lower part. The upper part of the trapezoid forms a circular blocking plate recessed inward, and the lower part extends horizontally as a guide- An upper end of the guiding edge portion is curled so as to prevent inflow of rainwater, and a guiding edge portion corresponding to a distance smaller than the guiding edge portion is formed in the end portion of the guiding edge portion A lower cylinder connected to the upper cover and the induction softening portion at an opening interval by forming a curled portion to be curled, a mesh plate interposed between the upper cover and the lower cylinder, An elongated bolt passing through the guiding edge portion of the upper cover to be engaged with the elongated bolt, And a guiding surface extending horizontally in the lengthwise direction of the tubular body so as to guide the air stream, wherein the guiding surface of the tubular body is formed such that a long bolt passes through the gap between the upper cover and the lower tubular body And a ventilation hole for a duct which is made of a guide member made of a conductive material.

In addition, the ventilation device (ventilation hole fixing device) shown in Fig. 1C,

An outer housing which forms an edge portion formed with an engagement groove and a sealing groove on a cylindrical front end inner edge portion with a front end opened and a rear end portion which forms a latching portion engaged with the duct hole; A flange-like supporting member having a sealing groove for sealingly supporting the lower half of the inner housing, and a ring-shaped sealing member inserted into the sealing groove, respectively, (Registered No. 20-0466362).

The common point of the known non-powered indoor air flow exhaust devices is a natural exhaust structure that exhausts the indoor air flow as the air flow of the outside air. However, the common point of such structures is that the entrance interval of the outside air entering the inlet side, In the case of high-rise buildings where wind intensity is intensively introduced, as well as low-rise buildings or zones with no wind movement, they are installed at the same intervals, so that the indoor air can not be discharged due to strong winds, . This is because the ventilation and exhaust devices for ventilation of the building are constructed to have a constant outside air passage area (interval) without regard to the strength of the wind in the high-rise or windy areas or the highlands, .

Generally, the ceiling of the building is equipped with a ventilating system in which air is supplied and exhausted through a ventilating grill for opening and closing which is connected to an air supply duct and an exhaust duct. In such a ventilating facility, in the wintertime when the heating operation is performed, the ventilating grill for opening and closing is installed because the energy loss is increased due to the heating heat unnecessarily discharged through the ventilating grill for opening and closing and the room temperature is lowered. The ceiling ventilation grille that supplies the warm air is composed of two grill plates for opening and closing which form a plurality of semicircular holes so that the outer grill plate blocks the semicircular holes of the inner grill plate to block the supply of cold and warm air Or ventilating grill for supplying heating heat by opening a slot of an inner grill plate with an outer grill plate is known. However, this is a ventilating grill in which ventilation grilles for ventilation It is a grill.

Therefore, in an exhaust device having a non-powered natural exhaust structure that exhausts indoor air as an air stream of the outside air, the distance between the inlet and the outlet of the outside air is changed depending on the place where the wind intensity is strong and where there is little wind movement. A non-powered exhaust system capable of controlling the sub-gap is required.

In the conventional ventilation cap for a ventilation duct for a ventilation duct, since the ventilation duct has at least three bearing assemblies at the time of assembling the valve body and the ventilation duct body as an outer cover, the structure of the nut assembly is complicated. , And the installation process is increased.

The non-powered indoor air flow exhaust system of the present invention improves the problems and disadvantages described above, thereby suppressing the noise generated by the side flow airflow when the indoor airflow is raised to the outside as the side flow airflow by the external airflow, The purpose is to prevent the backward wind caused by the wind.

Particularly, according to the present invention, the spacing height of the outer cover member passing air flow of the outer assembly parts can be determined according to the floor and the altitude, and can be appropriately selected according to the exhaust amount of the indoor air flow or the size of the exhaust pipe.

Further, the present invention prevents the backward flow caused by strong winds from the outside of the indoor gas, prevents the foreign matter from flowing into the exhaust passage, makes it easy to fix the grill member, and prevents the grill member from flowing. Further, the present invention can facilitate the connection between the ventilation hole and the exhaust pipe or the assembly and connection between the respective parts, and prevent safety accidents due to handling of the ventilation hole. Further, the present invention can provide a non-powered exhaust device capable of adjusting the size of the exhaust port according to the wind intensity, and is easy to install, light in weight and low in unit cost, It is possible to prevent the occurrence of damage to the wall as well as the sink due to the water infiltrated by the backward wind as well as the prevention of the noise by the side passage airflow of the side wall.

It is an object of the present invention to provide a ventilation device capable of adjusting the distance between the inlet and the outlet of the air in an exhaust device having a non-powered natural exhaust structure for exhausting indoor air as the air flow of the outside air as described above.

An object of the present invention is to improve the exhaust effect of an indoor airflow by making it possible to adjust the passage area of an inlet portion through which wind is blown.

An object of the present invention is to improve the assemblability of the ventilator by allowing the outer cover member located at the outermost position of the ventilator to be fastened and assembled at the center of the ventilator main body.

The present invention relates to a ventilation device comprising an outer cover member, an outer air guide member, a porous mesh plate and a ventilation main body, which is fastened, adjusted and assembled with a central axis extending from the outer cover member, The present invention is also directed to providing a ventilation device having a fastening structure by introducing a fastening structure that can be fastened at a non-position.

The main object of the present invention is to provide a central assembling structure between the outer cover member, the outer air guide member and the ventilation main body by changing the assembling structure of the ventilation device installed in the ventilation duct for indoor ventilation of the building.

The present invention can adjust the wind passing area formed between the outer cover member and the airflow guide part (hereinafter also referred to as an inlet and an outlet part interval) so that the wind strength becomes stronger (for example, (A) of the ventilation device (hood cap) installed in the exhaust duct (such as a ventilation duct) is designed to be narrow, and in a place where the wind intensity is weak (such as a basin surrounded by a lowland or a mountain) It is an object of the present invention to provide a ventilation device capable of achieving the above objects by simply adjusting the vertical height of the outer cover member by fabricating a ventilation device whose design value can be adjusted relatively widely.

In order to achieve the above object, the present invention provides a non-

An outer cover member having a circular plate body and having a fourth spiral formed at the lower end of the inner central portion thereof and having a major axis downward; Wherein an exhaust passage passage in which a longitudinal axis of the outer cover member is located is formed at a central portion of the plate member and an inclined surface inclined downward at a predetermined angle is formed in the exhaust passage, An outside air guide member having a fastening hole formed at a predetermined position on an inclined surface; An insect valve plate having a shaft hole formed in a center portion toward the exhaust passage of the outside air guide member and having a long axis in a spiral shape and a fastening hole formed in the outer periphery; An exhaust port body which is a cylindrical wall portion inserted into an exhaust duct and which has an enlarged surface portion corresponding to a bottom surface of the outside air guide member in the exhaust progressing direction at an upper end side of the cylindrical wall portion and in which a fastening hole is formed; And a fastening member passing through the fastening holes of the outside air guide member, the fastening holes of the insectproof plate and the fastening holes of the exhaust hole main body, and fastened as a nut; Wherein the air-exhausting device is a non-powered indoor air flow exhausting device.

In order to achieve the above object, the outer cover member of the non-powered indoor air flow exhaust system of the present invention preferably forms a stay space in which inflow air instantaneously flows between the outer cover member and the outer air guide member.

In order to achieve the above object, a wide inlet / outlet portion through which an external airflow passes is formed between the outer cover member and the outside air guide member of the non-powered indoor air flow exhaust system of the present invention, and the center portion thereof has a narrower width It is preferable to form an exhaust passage through which the indoor airflow is exhausted from the neck portion to the neck portion.

In order to achieve the above object, the outside air guide member of the non-powered indoor air flow exhaust system of the present invention preferably comprises a horizontal plane extending from the inclined plane and a cylindrical plane wall extending downward from the horizontal plane.

In order to accomplish the above object, the long axis of the non-powered indoor air flow exhaust system of the present invention is characterized in that a nut is fastened before inserting the shaft hole, and after passing through the shaft hole, a nut is screwed into the shaft to adjust the length of the long shaft, The distance between the mouth and the outlet is adjustable.

In order to accomplish the above object, the present invention provides a non-powered indoor air flow exhaust system, comprising: an upper end portion of the long axis and an inner circumferential surface groove portion of a center portion of the outer cover member, The inner peripheral surface groove portion of the central portion of the member may be formed with a helical groove so that the upper portion of the long axis is engaged with the screw.

In order to achieve the above object, the screen panel of the non-powered indoor air flow exhaust system of the present invention is preferably a perforated plate having a plurality of through holes.

In order to achieve the above object, the gap (a), the gap (b), and the gap (c) of the exhaust passage of the non-powered indoor air flow exhaust system of the present invention are defined by the following equation (1) 1) P ₁ = P ₂ + 1 / 2ρ (V ₂ ² -V ₁ ² ), where ρ is the density of the gas (1,000 kg / m 3)
It is preferable that the ratio of the inlet / outlet spacing (a): neck spacing (b): exhaust passage (c) is 7.0: 2.2 to 2.8: 1.0.

As described above, according to the present invention, the indoor airflow non-powered ventilating apparatuses using the outside air in the related art are commonly used as a coupling structure in which a plurality of outdoor air guide members are stacked and assembled as shown in FIGS. 1A, 1B, In the present invention, the coupling structure of the outer cover member is made to be connectable at the central axis so that it is formed between the outer cover member and the outer air guide member (Hood cap) installed in an exhaust duct such as a high-rise building or a highland in which wind strength is varied by adjusting the passage area of the wind (the distance between the mouth and the outlet) (a) in a place where the wind strength is weak, and in a place where the wind strength is strong, the distance between the mouth and the outlet (a) can be adjusted to be small. It is possible to improve the ventilation efficiency of the indoor airflow by providing the ventilator with the inlet (outlet) spacing (a) adjusted according to the wind strength.

The present invention can adjust the interval (passage area) between the inlet and outlet portions of the outside air (outside wind) as described above, thereby improving the exhaust effect of the indoor airflow that is raised by the negative pressure, The outer cover member can be fastened and assembled at the center of the vent hole main body and the outer air guide member provided between the outer cover member and the outer cover member can be assembled at a position other than the central axis It is possible to provide a ventilation device with improved assemblability that can be assembled and assembled.

The exhaust device having a non-powered natural exhaust structure according to the present invention suppresses the noise generated by the side passage air flow when the indoor airflow is drawn up by the air flow passing through the side of the outside air according to the Bernoulli theorem, It is possible to prevent the backward wind caused by the strong wind of the wind.

Further, the present invention provides a non-powered exhaust system in which the height of the external assembled parts can be adjusted according to the level and the altitude and can be appropriately selected according to the exhaust amount of the indoor air flow or the size of the exhaust pipe. .

In addition, the present invention has the effect of preventing the backward flow caused by strong winds from the outside of the indoor gas, preventing the foreign matter from flowing into the exhaust passage, and facilitating the connection of the exhaust pipe or the assembly and connection between the components.

Further, the present invention can provide a non-powered exhaust device capable of adjusting the size of the exhaust port according to the wind intensity, and is easy to install, light in weight and low in unit cost, The side air passing through the side air stream prevents the generation of noise as well as damage to the wallpaper and the sink due to the water infiltrated by the backward wind.

FIGS. 1A, 1B and 1C are views showing examples of indoor air flow ventilators using a known outdoor air,
2 is an external perspective view of the non-powered indoor air flow exhaust system of the present invention,
3 is an exploded perspective view of the non-powered indoor air flow exhaust system of the present invention,
4A, 4B and 4C are sectional views of a non-powered indoor air flow exhaust system according to the present invention,
5A and 5B are plan views showing an example of an insectproof valve body of the non-powered indoor air flow exhaust system of the present invention,
Figs. 6A, 6B, 6C and 6D are enlarged views of the " A "part of the central long axis of the non-powered indoor air flow exhaust system of the present invention,
FIGS. 7A, 7B and 7C are enlarged views of the "B" portion of the non-powered indoor air flow exhaust system of the present invention,
8A and 8B are schematic views for explaining the principle of the non-powered indoor air flow exhaust system of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a non-powered indoor air flow exhaust system according to the present invention will be described in detail with reference to the accompanying drawings.

3 is an exploded perspective view of the non-powered indoor air flow exhaust system of the present invention, and FIGS. 4A, 4B, and 4C are views showing a state in which the non-powered indoor air flow exhaust system of the present invention 6a, 6b, 6c and 6d are plan views showing examples of the insecticidal valve element of the non-powered indoor air flow exhaust system of the present invention, and Figs. 6a, 6b, 6c and 6d are cross- Figs. 7A, 7B and 7C are enlarged views of the "B" part of the non-powered indoor air flow exhaust system of the present invention.

As shown in the drawings, the non-powered indoor air flow exhaust system of the present invention mainly comprises an outer cover member 20, an outer air guide member 30, an insectproof plate member 40, an exhaust port body 10, and a fastening member 50 (Hereinafter, referred to as " non-powered indoor air flow exhaust ") in which the indoor air flow is naturally exhausted by the strength of the wind outside the building.

First, the exhaust port body 10 of the present invention forms a tubular body of a hood cap (ventilation port) inserted and installed in a generally ventilated exhaust duct (vent hole for cooking hood vent) And the upper end side of the cylindrical wall portion 11 forms an enlarged surface portion 12 corresponding to the bottom surface of the outside air guide member 30 in the exhaust progressing direction, The fastening hole 13 can be formed at a predetermined position of the base 12.

The outer cover member 20 may have a circular plate shape of a predetermined shape having a circular rim of the rim and a retention space 24 at an inner central portion thereof. As shown in FIGS. 3 and 4A, The indoor airflow of the exhaust passage 31 can be appropriately discharged according to the flow of the external airflow. As shown in Fig. 8A, this indoor airflow conveys the stay space 24 without concave, for example, to form a narrowed neck portion of the venturi pipe. The formation of the retention space 24 may be designed in consideration of the strength and the area of the indoor air flow passing through the exhaust passage 31, which will be described later.

The long axis 21 may be vertically downwardly formed at the center of the bottom surface of the outer cover member 20. As shown in Fig. 7 (b), the long shaft 21 can be integrally coupled to the fixing groove 22 formed at the center of the outer cover member 20 by high-frequency thermal fusion bonding. Alternatively, as shown in Fig. 7 It is possible to form the spiral 22a in the fixing groove 22 and to join with the first spiral 21a of the long axis 21.

On the other hand, as shown in FIG. 4B, the outer cover member 20 can be a cylindrical body having a closed upper portion and an open lower portion and having a deep wall.

4C, the outer cover member 20 can be a cylindrical shape in which the upper portion is clogged and the lower portion is opened and the side wall is inclined to a deep and sufficiently wide range.

The outside air guide member 30 can form a relatively wide area (width, spacing, and spacing) between the inlet and outlet portions a so that external wind passes between the outside air guide member 30 and the edge portion of the outer cover member 20. This can be carried out as a part forming the gas passage area of the inlet and outlet of the known venturi pipe as described later.

Therefore, the center portion of the outside air guide member 30 forms a circular narrowed opening portion, which corresponds to the wide inlet / outlet portion a through which the outside air passes, and is provided at a predetermined position where the narrow neck portion b is formed. The exhaust passage 31 can be vertically formed so as to form a negative pressure at a designed interval (the space excluding the major axis at the center in the drawing can be interpreted as the passage area).

The position where the exhaust passage 31 is formed has a predetermined height at the cylindrical wall portion 35. The inclined face 32 is formed downward from the surface of the cylindrical wall portion 35 and then connected to the horizontal face 34, At least two fastening holes 33 may be formed at predetermined positions of the fastening holes 33a. In the embodiment of the present invention, four places are formed in the drawing. The tubular wall 35 can be formed by forming at least one inclined surface downwardly in contact with the horizontal wall 34 so as to be in close contact with the building wall surface. The inclined surface 32 may form an inclined surface 32 or a curved surface that forms a rising air flow at a position beyond the above-mentioned wide-width inlet and outlet space a in which the above-described wind enters.

The insectproof plate 40 has a plurality of through holes 42 through which a room air stream is exhausted on a circular plate surface and a central portion thereof forms a shaft hole 43 to which the long axis 21 is adjustably coupled, A plurality of the fastening members 52 may be formed to be fastened as the nuts 53 which are fastened through the fastening holes 33 and below the fastening holes 44. [ 5A and 5B, the insectproof plate 40 has a narrow space between the outer cover member 20 and the outside air guide member 30 so as to prevent foreign matter, Or can be formed to be wide.

The fastening member 50 includes bolts 51 and nuts 53 and a nut 54 positioned in front of the shaft hole 43 before the long shaft 21 is passed therethrough, The nuts 51 that are screwed to the lower end helical 21b of the one long shaft 21 can be collectively referred to. Also, when the bolt 52 is made rivet, the second nut 53 for fastening the lower side of the bolt 52 may be unnecessary.

Hereinafter, the arrangement structure of the fastening member 50 and the long shaft 21 will be described.

That is, the long axis 21 is coupled with the first and second helices 21a and 21b on the upper and lower sides of the long axis 21, respectively, and can be coupled thereto by screwing or by RF welding. 6A, 6B, 6C, and 6D which are enlarged views of Figs. 4A, 4B and 4C, respectively.

The third spiral 22a can be formed in the groove 22 corresponding to the first spiral 21a as shown in Fig. The coupling of the long shaft 21 coupled to the center of the inner circumferential surface of the outer cover member 20 can be coupled to the groove 22 by high frequency thermal welding as shown in FIG.

As shown in Fig. 6C, the recess 27 and the through hole 28 formed in the central portion of the outer cover member 20b are passed through as the bolt 25, and the leading end of the long shaft 21 is assembled correspondingly can do. A fastening hole 21c formed with a helix (not shown) can be formed at the tip of the long shaft 21. In the case of the outer cover member 20a, the protective cap 26 may be laminated and bonded (heat-sealed).

As shown in Fig. 6 (d), to the fixing groove 22 formed in the thick portion 23 at the center of the bottom of the outer cover member 20b of Fig. 4 (c). In the case of the outer cover member 20b, the upper end of the long axis 21 may be joined by a method such as high-frequency thermal fusion without being screwed on the bottom surface of the outer cover member 20b.

The lower joint of the long shaft 21 will be described with reference to Figs. 7A, 7B and 7C which are enlarged views of Figs. 4A, 4B and 4C.

The lower coupling of the long shaft 21 of the present non-powered indoor air flow exhaust system shown in Fig. 7A is formed by positioning the second spiral 21b of the long shaft 21 as a nut 54, (43) and screwed into the nut (51) to adjust its position.

The lower coupling of the long shaft 21 of the present non-powered indoor air flow exhaust system of the present invention shown in Fig. 7B is achieved by the second spiral 21b of the long shaft 21 being inserted into the fifth spiral 43a formed in the shaft hole 43, Can be combined while adjusting.

The lower coupling of the long shaft 21 of the present non-powered indoor air flow exhaust system of the present invention shown in Fig. 7C is such that the long shaft 21 is screwed as a nut 51 from the lower side of the shaft hole 43, The length of the screwing of the long shaft 20 integrally coupled to the outer cover member 20 as the nut 54 can be adjusted.

In assembling the non-powered indoor air flow exhausting apparatus of the present invention, the long axis 21 is integrally formed on the inner bottom portion of the outer cover member 20 to form the first body.

The fastening member 52 and the nut 53 are inserted through the fastening hole 33 of the outside air guide member 30, the fastening hole 44 of the insectproof plate 40 and the fastening hole 13 of the exhaust port body 10, ) To assemble the first body.

7b). When the long shaft 21 of the outer cover member 20 is screwed into the shaft hole 43 of the assembled second body (FIG. 7b) or when assembling the long shaft 21 as shown in FIGS. 7a and 7c So that the assembly of the non-powered indoor air flow exhaust system of the present invention is completed.

Particularly, the adjustment of the height of the long shaft 21 when the long shaft 21 is fixed is as described above, the outer air passage inlet / outlet gap a of the outer cover member 20 coupled to the upper end of the long shaft 21 can be adjusted.

The adjustment of the outside air passage inlet / outlet spacing (a) will mean controlling the exhaust amount of the indoor airflow passing through the exhaust passage 31 of the present invention. This is in accordance with the principle of the venturi tube that the air flow in the direction perpendicular thereto by the air flow pressure flowing in the outer passageway on the horizontal line of the T-shaped passageway, as is known, is raised and exhausted by obtaining a negative pressure proportional to the predetermined formula.

Therefore, if the distance (a) between the inlet and outlet of the outside air becomes narrow, the pressure (flow area of the passing air) of the passing air flow becomes smaller, so that the room air flow in the vertical direction in the vertical direction is reduced in proportion thereto, (a) is widened, the amount of exhaust passing through the exhaust passage 31 passing through the exhaust duct from inside the room will also increase.

The present invention is characterized in that an exhaust passage is formed at a central portion between the outer cover member and the outside air guide member and the exhaust passage 31 through which the wind passes through the outside air inlet / The exhaust of the room air through the fan will also be non-powered without the application of power (drive motor and fan). This is because the indoor air discharged from the air outlet main body 10 to the exhaust passage 31 can be discharged by the Venturi tube (Bernoulli theorem) when the non-powered indoor air flow exhaust device of the present invention is installed in the exhaust hood of the building.

This will be briefly described with reference to FIGS. 8A and 8B of the accompanying drawings.

The configuration of the venturi pipe of the ventilator shown in Fig. 8A is applied to another embodiment of the present invention. In numerical analysis, the shape of the outer cover member 20 is the same as that of the neck portion b And the exhaust passage 31 of the outside air guide member 30 should also be adjusted by the design value.

That is, when a predetermined amount of the external gas passes through the neck portion (b) of the venturi tube having a small diameter and passing through the outside air passage inlet / outlet portion spacing a having a large diameter of the venturi tube, the following equations (1) and Bernoulli's equation) increases the velocity of airflow in the neck (b) and decreases the pressure.

[Equation 1]

Q = Q1 = Q2, A1V1 = A2V2,? / 4D1 ² V1 =? / 4D2 ² V2

&Quot; (2) "

P1 / ρ + 1 / 2V1 ² = P2 / ρ + 1 / 2V2 ²

When the outside air passage inlet / outlet space a between the outer cover member 20 and the outside air guide member 30 according to the above formula is 7 cm, the diameter of the venturi tube neck portion b is 2.2 to 2.8 cm desirable. That is, in general, the exhaust amount per hour of the ventilation device using outside air was set at 120 (liters) as the fluid amount, the passing air amount (fluid amount) was set at 2.0 liters per minute, and the inside diameter of the vertical exhaust path was set at 7.0 cm As a result, the passing pressure (P ₁ ) was found to be 0.36 kgf / ㎠, and the flow rate was 0.80 to 0.9 m per second, which was 0.86 as calculated by the following equation.

That is, V ₁ = Q / A ₁ = 0.000033 m 3 / s [(0.007 m) ² (π / 4)] = 0.86 m / s

V 1 represents the flow rate per second (m / s) at the passage inlet a of the outside air, Q represents the amount of passing gas (m 3 / s), A ₁ represents the outside air passage entrance, Sectional area (m < 2 >).

(A) of 7.0 cm and the diameter (D ₂ ) of the middle neck part (b) was changed to 2.0 cm, 2.5 cm and 3.0 cm, the flow rate at the neck part (b) V ₂ ) and the in-pipe pressure (P ₂ ) were calculated by the following equation (Bernoulli equation), and the results are shown in Table 1.

&Quot; (3) "

P ₁ = P ₂ + 1/2? (V ₂ ² -V ₁ ² )

Wherein, P ₁ denotes a through pressure in the passage of the outside air inlet (a), P ₂ denotes a neck portion (b) in vitro pressure, ρ is the density (1,000 kg / ㎥) of the gas, V ₁ has inlet and outlet gap (a), and V ₂ represents the flow rate of the neck portion (b).

           D (cm)     V2 (m / s)    P2 D ₁ D ₂ Pa (Pascal) kgf / cm ² 7.0 2.0 10.5 -1.950 -0.2 7.0 2.0 6.7 13,200 0.135 7.0 2.0 4.7 24,600 0.250

As can be seen from the above table, as the diameter of the neck portion (b) becomes narrower, the flow velocity in the neck portion (b) becomes the reciprocal of the square of the ratio of the diameter of the neck portion (b) , And the pressure in the pipe (b) increased more than 1.5 times the diameter increase rate as the diameter increased.

When the diameter of the neck portion b is set to 2.0 cm, the pressure in the pipe becomes negative so that the exhaust passage 31 can reach the neck portion b along the exhaust passage 31 in a state where the exhaust amount is not controlled have. The distance (c) between the exhaust passages 31 is divided into two sides in the drawing, but actually, the passing area excluding the area of the long axis at the center is calculated.

Therefore, when the clearance between the outer cover member 20 and the outside air guide member 30 is 7 cm, the diameter of the venturi tube portion b is 2.2 to 2.8 cm And is controllable within this range. Preferably, the diameter of the venturi tube portion (a) is 2.5 cm. (A) of the venturi tube portion (b) is 7 cm when the outside air passage inlet and outlet portion spacing (a) is approximately 7 cm as is schematically shown in the cross-sectional view of the line a-a ', line b- It is preferable that the diameter of the exhaust passage 31 is 2.5 cm, and the diameter of the exhaust passage 31 is 1.0 cm.

That is, it can be seen that the ratio of the inlet-outlet interval (a): the neck interval (b): the exhaust passage (c) is 7.0: 2.2 to 2.8: 1.0.

The assembling of the ventilation device using the air flow outside the present invention as described above is performed by sequentially positioning the exhaust port main body 10, the outside air guide member 30 and the insectproof plate 40, and then fastening the respective fasteners 33 Through the nuts 51 at the bottom surface of the enlarged surface portion 12 of the exhaust port main body 10 after passing through the holes 44, The long axis 21 of the outer cover member 20 is screwed to the shaft hole 43 from above and assembled to the air outlet main body 10 while adjusting the height. The adjustment of the long axis 21 can be adjusted by considering the passage area of wind entering the inlet between the outer cover member 20 and the outside air guide member 30 as described above.

As described above, the indoor airflow non-powered ventilation devices using the outside air in the related art generally have a coupling structure in which a plurality of outdoor air guide members are stacked and assembled as shown in FIGS. 1A, 1B and 1C, There is no design of a structure that interferes with the guidance of the airflow in the direction of introduction. However, the present invention enables the coupling structure of the outer cover member to be coupled at the central axis, whereby the passage area of the wind formed between the outer cover member and the outer- (A) through which the outside air of the ventilation device (hood cap), which is installed in the high-rise building or the high-level exhaust duct such as the highland, (A) in the place where the intensity of the wind is strong and the center axis is adjusted so that the gap (a) By providing been able to install a ventilation inlet and outlet spacing (a) is adjusted to the intensity of the wind to improve the exhaust efficiency of the indoor air flow.

In other words, it is possible to adjust the interval (passage area) of the inlet portion where the outside air (outside wind) is reduced as described above, thereby improving the exhaust effect of the indoor airflow which is raised by the negative pressure, and at the same time, The ventilation hole can be assembled and assembled at the center of the ventilation hole main body.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. I will understand. Therefore, the true scope of technical protection of this invention should be determined by the utility model registration claim scope.

 The present invention relates to an exhaust gas purifying apparatus and a method of manufacturing the same, and more particularly, to an exhaust gas purifying apparatus, The outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface of the outer peripheral surface, Wherein the bolt is inserted into the hole of the bolt and the bolt is inserted into the through hole of the bolt,

Claims (9)

A non-powered indoor air flow exhaust system,
An outer cover member having a circular plate body and having an inner central portion formed with a fourth spiral downward at a lower end thereof and a stay space in which inflow air is instantaneously flowed downward;
An outer cover member having a circular plate body and a long axis formed by a fourth helical line formed at a lower end thereof downward at an inner central portion thereof and forming a retention space in which inflow air instantaneously flows downwardly below the plate body;
Wherein an exhaust passage passage in which a longitudinal axis of the outer cover member is located is formed at a central portion of the plate member and an inclined surface inclined downward at a predetermined angle is formed in the exhaust passage, An outer air guide member forming a horizontal plane extending from an inclined plane, forming a fastening hole in at least two locations in a predetermined position of the horizontal plane, and forming a cylindrical wall face extending downward from the horizontal plane;
An insulator body having a shaft hole formed in the central portion of the outer air guide member toward the exhaust passage and having a major axis aligned with the fourth spiral and having a fastening hole formed in the outer periphery thereof;
An exhaust port body which is a cylindrical wall portion inserted into an exhaust duct and which has an enlarged surface portion corresponding to a bottom surface of the outside air guide member in the exhaust progressing direction at an upper end side of the cylindrical wall portion and in which a fastening hole is formed; And
A fastening member which is threaded through the fastening holes of the outside air guide member, the fastening holes of the insectproof plate and the fastening holes of the exhaust hole main body;
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A wide inlet / outlet portion through which an external airflow passes is formed between the outer cover member and the outside air guide member, and a central portion thereof forms a neck portion having a narrower width than the mouth portion and the outlet portion, and the indoor airflow is discharged downward from the neck portion Forming an exhaust passage,
The long axis,
Wherein a distance (a) between an inlet and an outlet through which the outside air passes is adjustable by screwing and screwing together the shaft hole and adjusting the length thereof. delete delete delete delete The non-powered indoor airflow exhaust system according to claim 1, wherein the upper end of the long axis and the inner peripheral surface groove portion of the central portion of the outer cover member are joined by ultrasonic thermal welding. 2. The non-powered indoor air flow exhaust system according to claim 1, wherein a first spiral is formed on an upper portion of the longitudinal axis, and a spiral groove is formed in an inner peripheral surface groove portion of a center portion of the outer cover member, . The non-powered indoor airflow exhaust system according to claim 1, wherein the insectproof valve element has a plurality of through holes. The method according to claim 1,
The distance (a) between the inlet and outlet portions, the interval (b) between the neck portions, and the interval (c) between the exhaust passages are defined by the following equations,
P ₁ = P ₂ + 1/2 ρ (V ₂ ² -V ₁ ² ) where p is the density of the gas (1,000 kg / m 3), P ₁ is the passing pressure at the inlet (a) ₂ denotes the pressure in the pipe (b), V ₁ denotes the flow velocity of the inlet / outlet gap (a), and V ₂ denotes the flow velocity of the neck portion (b).
Wherein a ratio of the inlet / outlet spacing (a): the neck spacing (b): the exhaust passage (c) is 7.0: 2.2 to 2.8: 1.0.

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