KR100515084B1 - Ventilation system - Google Patents

Abstract

The present invention relates to a ventilation system structure inside the building that collects dust generated in the room and maintains a comfortable indoor space at all times through ventilation, and is installed at four corners in an interior space surrounded by a square wall. In the surface exposed by the housing having an inlet opening to open the inner cylindrical rotating space and the communication line cut in the longitudinal direction, the groove formed in the bottom of the housing, the dust is inserted into the groove and falling from the rotating space A bottom plate tapered in a normal and narrow shape with a dust collection box for collecting a back and a space disposed between the groove and the rotating space and having a hole communicating with the groove and the rotating space at the center thereof, and a discharge cut along the edge A cover inlet having a hole and covering the upper surface of the housing and closing the cover; Four are arranged in a square to be paired with the four inlet in the ceiling of the indoor space, the opening formed in each of the inlet facing the same rotation direction while facing the corresponding inlet formed in the opposite position; The output port is built into the wall and the end thereof is engaged with the communication line while the air is discharged comprises a wind turbine that is directed so that the discharged air can be moved along the inner circumferential surface of the rotation space, the wind turbine and An intake line piped to supply external air to the inlet; An exhaust line piped to exhaust air discharged from an exhaust pipe communicating with the cover at an upper side of the rotation space to the outside; And, it is made of a fan installed respectively to induce airflow in the intake line and exhaust line.

Description

Ventilation system inside the building

The present invention relates to a ventilation facility structure inside the building to collect dust generated in the room and maintain a comfortable indoor space through ventilation.

The interior is a space that is enclosed with the outside and changes in the composition of the air as well as various dusts through the breathing and activity of the occupants. Therefore, the building is provided with a ventilation facility for indoor ventilation, and also provided with a dust collector and the like for removing various dust generated indoors.

However, the ventilation system has a low efficiency because it is only partly ventilated in the entire indoor space through the ventilation hole fixed at a specific point. In addition, in a closed room in which the conventional ventilation mechanism is installed, an unpleasant environment is created while the air flow is not made smoothly, or the still state is almost stopped, thereby limiting indoor activities.

In addition, dust collectors are installed to remove various dusts floating in the room, but this gave an economic burden of purchasing separate items.

Accordingly, the present invention has been devised to solve the above problems, while creating a comfortable indoor environment with ventilation to optimize air composition while generating a continuous air flow, and remove indoor dust and the like without economic burden. The purpose is to provide a ventilation system structure inside the building to maintain a more clean indoor air.

In order to achieve the above object, the present invention,

In the interior space where the wall is surrounded by a square, each of the four corners is provided on the outer surface of the housing having an inlet opening for opening the inner cylindrical rotating space and a communication line cut in the longitudinal direction and formed on the bottom of the housing And a dust collecting box for removing dust falling from the rotating space, the groove being inserted into the groove, and arranged between the groove and the rotating space to store them, and having a hole in the center for communicating the groove with the rotating space. A suction port having a bottom plate tapered in a narrow shape and a cover configured to cover and close the upper surface of the housing with a discharge hole cut along an edge thereof;

Four are arranged in a square to be paired with the four inlet in the ceiling of the indoor space, the opening formed in each of the inlet facing the same rotation direction while facing the corresponding inlet formed in the opposite position;

The output port is built into the wall and the end thereof is engaged with the communication line while the air is discharged comprises a wind turbine that is directed so that the discharged air can be moved along the inner circumferential surface of the rotation space, the wind turbine and An intake line piped to supply external air to the inlet;

An exhaust line piped to exhaust air discharged from an exhaust pipe communicating with the cover at an upper side of the rotation space to the outside; And,

A fan installed to induce air flow in the intake line and the exhaust line;

Ventilation structure inside the building consisting of.

In the ventilation equipment structure inside the building according to the present invention,

The output port is formed long along the longitudinal direction of the housing, so that it is easy to accelerate the whirlwind generated in the rotation space;

The side of the rotation space of the inlet further comprises a guide that inclined a portion of the inlet in the air flow direction in order to minimize the interference of the air flow in the rotation space.

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

1 is a view schematically showing the overall appearance of the ventilation system structure according to the present invention will be described with reference to this.

Ventilation structure according to the present invention, the wall 11 is installed in each of the four corners in the interior space 10 enclosed by a square to open the inner cylindrical rotating space 212 (see Fig. 2) on the surface exposed to the outside A housing 210 (see FIG. 2) having an inlet port 211 (see FIG. 2) and having a longitudinally cut communication line 213 (see FIG. 2), and a groove 220 formed at the bottom of the housing 210; 2) and a dust collection box 230 which is inserted into the groove 220 and collects dust D falling from the rotation space 212. 2) and a hole disposed between the groove 220 and the rotational space 212, the center of which has a hole 241 (see Fig. 2) for communicating the groove 220 and the rotational space 212 at the center thereof. A cover 250 having a bottom plate 240 (see FIG. 2) tapered in an ordinary light narrow shape and a discharge hole 251 (see FIG. 2) cut along an edge to cover and close the top surface of the housing 210; A suction port 200) (see FIG. 2);

Four are arranged in a square to be paired with the four intake port 200 in the ceiling of the indoor space 10, while the openings (not shown) formed in each facing the corresponding intake port 200 formed in the opposite position Injection holes 100 directed in the same rotational direction;

The output port 31a (see FIG. 2), which is embedded in the wall 11 and its end is engaged with the communication line 213, and the air is discharged, is moved along the inner circumferential surface of the rotating space 212. An intake line 30 including a wind generating port 31 (see FIG. 2) oriented so as to be provided, and piped to supply external air to the wind generating port 31 and the inlet 100;

An exhaust line 40 piped to exhaust air discharged from an exhaust pipe 41 (see FIG. 2) communicating with the cover 250 above the rotation space 212 to the outside; And,

Ventilators 21 and 22 are respectively installed to cause airflow in the intake line 30 and the exhaust line 40.

As described above, the ventilation equipment structure according to the present invention is not significantly different from the conventional equipment structure in the manner of exchanging air remaining in the indoor space 10 with the outside air, and its application and installation are not difficult. However, the effect shows a big difference through the technical idea described below.

First, the ventilation apparatus structure according to the present invention is provided with the inlet port 100 and the inlet port 200 corresponding to the inlet port 100. At this time, the injection hole 100 is a place for injecting the outside air introduced through the intake line 30 into the indoor space 10 is disposed at each corner on the ceiling portion of the indoor space (10). At this time, the opening (not shown) of the injection hole 100 is directed toward the suction ports 200 respectively installed at four corners in the four interior spaces 10 surrounded by the wall 11. The opening is a place where the outside air is discharged to the indoor space 10, toward the suction port 200, the discharged outside air moves toward the suction port (200). On the other hand, it is preferable that the opening does not face the adjacent inlet 200 as much as possible.

That is, as shown in Figure 1, the opening is located toward the inlet 200 is disposed in a position opposite to the inlet 100, the outside air discharged through the opening to the air flow activation of the indoor space (10) Can contribute.

On the other hand, since the opening is provided in each of the four injection holes 100, the openings formed in each injection hole 100 is preferably positioned to face the same rotation direction. In FIG. 1, the airflow of the indoor space 10 occurs counterclockwise while the openings are uniformly positioned in the counterclockwise direction toward the respective inlets 200. This can be expected to indirect ventilation effect through the continuous air flow, to move the dust contained in the air toward the inlet 200, which is a kind of dust collector to achieve a uniform dust removal effect of the entire interior space (10). For sake.

The inlet 100 receives external air from the intake line 30. Accordingly, the intake line 30 protrudes outward at its end for intake of external air. In addition, it is preferable to increase the suction output of the external air through the intake line 30 by providing one or more fans 22 to forcibly suck the outside air.

Subsequently, the intake line 30 also supplies external air to the intake port 200.

Figure 2 is a perspective view showing an exploded view of the inlet in accordance with the present invention, Figure 3 is a cross-sectional view showing the operation of the inlet according to the invention, Figure 4 schematically shows the operation of the inlet according to the invention A perspective view will be described with reference to this.

The suction port 200 includes a housing 210 having a cylindrical rotating space 212. The inner rotating space 212 of the housing 210 is a place where the outside air flows in one direction and the whirlwind is generated. The inflow dust can be separated without a separate filter. On the other hand, the whirlwind generated in the rotation space 212 is relatively reduced in the air pressure in the rotation space 212 generates a suction force that can suck the air in the indoor space (10). In addition, an inlet 211 communicating with the rotating space 212 is formed on one surface of the housing 210 to suck the air in the indoor space 10 using the suction force.

At this time, the inlet 211 is formed long in the vertical direction and short in the horizontal direction in order to increase the suction effect by the pressure difference. This is to increase the concentration of the suction force generated on the same height line of the whirlwind is a horizontal rotation in which the whirlwind generated in the rotation space 212 is formed vertically long.

On the other hand, as described above, the opening of the inlet 100 is directed toward the opposite inlet 200, the suction efficiency through the inlet 211 is further increased.

The housing 210 is a part of the wall 11 that forms the interior space (10). This is to reduce as much as possible the space occupied by the suction port 200 in the indoor space (10). Therefore, the inlet 211 will be formed only on one surface of the housing 210 exposed to the outside. On the other hand, the supply of external air for generating an artificial whirl in the rotating space 212 is made through the wind generating port 31 which is one component of the intake line (30). The wind turbine 31 has a distal end communicating with the rotating space 212 so that the external air injected flows on the inner circumferential surface of the rotating space 212.

To this end, the output port 31a through which the external air is injected from the wind turbine 31 is located as shown in FIG. 3. On the other hand, the output port 31a is formed long vertically so that the whirlwind is generated up and down of the rotation space (212).

The drawn reference numeral "213" is a communication line, and is formed in the housing 210 so that the end of the wind generating port 31 is fitted so that the output port 31a can be located in the rotation space 212.

Withdrawal reference numeral "15" is an insertion groove, a space formed to embed the wind turbine 31 in the wall (11).

Subsequently, as illustrated in FIG. 3, external air that is transported through the wind turbine 31 and injected through the output port 31a generates whirlwind in the rotation space 212. Since the injection of the external air through the output port (31a) is kept constant and constant, the whirlwind also occurs at a substantially constant rotation speed. Thus, intake through the inlet 211 continues.

However, the tornado may be reduced in rotational force due to interference when moving air along the inner circumferential surface of the rotating space 212 via the inlet 211. In addition, as the air in the rotating space 212 moving through the open inlet 211 is discharged to the inlet 211, the suction force of the inlet 211 can be greatly reduced.

Accordingly, the side of the rotation space 212 of the inlet 211 is further included a guide 214 that inclined a portion of the inlet 211 in the air flow direction to minimize the interference of the air flow in the rotation space 212 Can be.

The outside air injected through the wind turbine 31 generates a whirlwind in the rotating space 212. This continuous whirlwind sucks the air in the indoor space 10 and also sucks in the dust D contained in the air. At this time, the sucked dust (D) is aggregated while gathered to the center of the rotation space 212, and thereby falls due to the density increase.

At this time, the dust collection box 230 is disposed below the rotating space 212. The dust container 230 is to facilitate the collection and removal of the dust (D), the groove 220 is stored is formed in the dust container 230 to be inserted and removed in a drawer type. On the other hand, the groove 220 is partitioned between the rotary space 212 and the bottom plate 240, the center of the bottom plate 240 is formed with a hole 241 in which the dust (D) falls, It tapered to the shape which is normally light and narrow so that the fallen dust D can be guided to the said hole 241.

Subsequently, a cover 250 is covered on the top of the rotating space 212. The cover 250 is for compartmentalizing the exhaust pipe 41 which is a component of the rotation space 212 and the exhaust line 40, for discharging the external air continuously introduced through the wind turbine (31) It functions as an exhaust vent. At this time, the whirlwind generated in the rotating space 212 pushes the air toward the edge and collects dust into its center, so that the air is discharged so that only the air except the dust can be discharged through the exhaust pipe 41 as much as possible. Phosphorus discharge hole 251 is the cover 250 is formed along the edge.

As a result, as shown in Figure 4, the dust (D) is the center of the rotating space 212, the air is separated by the edge of the rotating space 212, and finally the dust (D) is dropped to collect the dust ( 230 is collected, and air is discharged to the exhaust pipe 41 through the discharge hole 251 of the cover 250.

The exhaust line 40 is for discharging the air transferred through the exhaust pipe 41 to the outside, it may be provided with one or more ventilator 21 to achieve a smooth air flow in the exhaust line (40). .

Unexplained withdrawal symbols "12, 13" are windows.

Unexplained withdrawal symbol "14" is an entrance.

According to the present invention as described above, by activating the air flow through the continuous generation of airflow in the interior and the closed interior space can create a more cool and light feeling environment, the dust removal and air composition ratio of the entire interior space By maintaining the uniformity of the balance it is effective to create a comfortable indoor environment.

1 is a view schematically showing the overall appearance of the ventilation system structure according to the present invention,

2 is an exploded perspective view showing a state of an intake port according to the present invention;

3 is a cross-sectional view showing the operation of the suction port according to the present invention,

Figure 4 is a perspective view schematically showing the operation of the suction port according to the present invention.

-Explanation of terms for main parts of attached drawings-

10; Indoor space 11; Wall

15; Insertion groove 21, 22; Ventilator

30; Intake line 31; Wind turbine

31a; Output port 40; Exhaust line

41; Exhaust pipe 100; Inlet

200; Inlet 210; housing

211; Inlet 212; Rotating space

213; Communication line 214; guide

220; Home 230; Dust box

240; Sole plate 241; hole

250; Cover 251; Discharge hole

D; dust

Claims (2)

In the interior space where the wall is surrounded by a square, each of the four corners is provided on the outer surface of the housing having an inlet opening for opening the inner cylindrical rotating space and a communication line cut in the longitudinal direction and formed on the bottom of the housing And a dust collecting box for removing dust falling from the rotating space, the groove being inserted into the groove, and arranged between the groove and the rotating space to store them, and having a hole in the center for communicating the groove with the rotating space. A suction port having a bottom plate tapered in a narrow shape and a cover configured to cover and close the upper surface of the housing with a discharge hole cut along an edge thereof; Four are arranged in a square to be paired with the four inlet in the ceiling of the indoor space, the opening formed in each of the inlet facing the same rotation direction while facing the corresponding inlet formed in the opposite position; The output port is built into the wall and the end thereof is engaged with the communication line while the air is discharged comprises a wind turbine that is directed so that the discharged air can be moved along the inner circumferential surface of the rotation space, the wind turbine and An intake line piped to supply external air to the inlet; An exhaust line piped to exhaust air discharged from an exhaust pipe communicating with the cover at an upper side of the rotation space to the outside; And, A fan installed to induce air flow in the intake line and the exhaust line; Ventilation structure inside the building, characterized in that consisting of. The method of claim 1, The output port is formed long along the longitudinal direction of the housing, so that it is easy to accelerate the whirlwind generated in the rotation space; The side of the rotation space of the inlet further comprises a guide for inclining a portion of the inlet in the air flow direction to minimize the interference of the air flow in the rotation space; Ventilation structure inside the building, characterized in that.