JP3415654B2 - Exhaust device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an exhaust system, and more particularly to an exhaust system that efficiently exhausts air in a space where harmful gas or dust is generated by a tornado flow without diffusing it into the surroundings.

[0002]

2. Description of the Related Art Heretofore, there has been known an exhaust device for trapping and exhausting air in a space where harmful gas or dust is generated without diffusing to the surroundings in order to efficiently exhaust harmful gas or dust. ing.

For example, in the draft chamber type exhaust device 100 shown in FIG. 8, in order to prevent the dust of the glass fiber 102 conveyed on the roller conveyor 101 from diffusing to the surroundings, a plurality of jets having a large number of jet ports in the axial direction are provided. The pipes 103 and 104 are installed horizontally, and the jet ports are arranged along the inner wall surface of the chamber.
A suction duct 106 is provided in the draft chamber 105 in the lateral direction. With such a configuration, a swirl flow having a central axis in the lateral direction is formed in the chamber, and the swirl flow captures the dust of the glass fiber 102, and the suction duct 10
It is possible to exhaust from 6.

However, in the draft chamber type exhaust device 100 described above, the jet pipes 103 and 104 for conveying the air toward the draft chamber 105 must be installed in the device, which greatly restricts the working space. In addition to the above, the draft chamber itself requires a relatively large volume, so that there is a problem that the degree of freedom of work is relatively small.

Further, in the tornado-type exhaust device 110 shown in FIG. 9, a plurality of vertical ducts 112 (four in the illustrated example) are arranged so as to surround the suction duct 111 arranged on the ceiling. A large number of air blowing nozzles 113 are vertically arranged in the vertical duct, and air is blown from the nozzles so that a swirling flow is generated in a space surrounded by the vertical duct. Due to the swirling airflow blown out, dust and toxic gas in the work space are conveyed to the suction duct 111 and exhausted.

However, since the tornado-type exhaust device 110 usually requires a gate-type vertical duct extending from the floor to the suction port of the ceiling, it is a large restriction to the working space and the vertical duct. Had to be installed in a limited number of positions, and there was a problem that the degree of freedom was low.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the conventional exhaust system as described above, and an object of the present invention is to provide a gate-column type vertical duct or a horizontal duct. Even if the device is not installed in a space where harmful gas, dust, etc. are generated, simply and efficiently installing a predetermined device on the ceiling part of the exhaust treatment space makes it easy and efficient.
By providing a new and improved exhaust device that can capture harmful gas and dust without diffusing to the surroundings and exhaust it, and can increase the degree of freedom of space utilization under the ceiling. is there.

[0008]

In order to solve the above-mentioned problems, according to the present invention, a gas supply means installed above the exhaust gas treatment space having a virtual axis and provided with air supply means for introducing outside air. An air chamber, a descending swirling airflow generating means for generating a descending swirling airflow around a side surface of a virtual cylinder that is inhaled from the air supply chamber and has a virtual axis of the processing space as a central axis, and upwards with respect to the processing space. Ri Do from with an upper extension to the intake air in the processing space from the intake port provided in the vicinity of an exhaust chamber having an exhaust means for exhausting to the outside of the virtual axis is installed, the downward swirling air flow generation means But,
One or more air supply openings that open to the air supply chamber
It has a hollow that allows it to rotate around the extension axis of the virtual axis.
The cylindrical member and the circumference of the hollow cylindrical member on the processing space side.
One or more branch pipes that branch in one direction and the branch
It is installed at the tip of the pipeline and opens downward in a substantially vertical direction.
Nozzle means, inside the hollow cylindrical member from the air supply port
The air introduced into the empty space passes through the branch line and from the nozzle means.
Generation of downward swirling airflow so that it is discharged to the processing space
An exhaust device is provided in which a passage is formed .

According to one embodiment of the present invention, the descending swirling airflow generating means has one or more air supply ports opening to the air supply chamber and is rotatable about an extension axis of the virtual axis. Hollow cylindrical member, one or more branch pipes branching in the circumferential direction on the processing space side of the hollow cylinder member, and nozzle means installed at the tip of the branch pipe and opening downward in a substantially vertical direction It is preferable that the air flow introduced into the hollow portion of the hollow cylindrical member from the air supply port is discharged from the nozzle means to the processing space through the branch pipe line to form a downward swirling air flow. To be done.

Further, the intake chamber and the exhaust chamber are formed in the same air chamber via a partition wall, and at that time, the intake chamber is arranged above the exhaust chamber to save the installation space. You can

Further, the intake port for introducing the air in the processing space into the exhaust chamber may be formed around the outer periphery of the hollow cylindrical member and introduced directly into the exhaust chamber from the intake port. In addition to the intake port, a second intake port is formed at the bottom of the hollow cylindrical member on the processing space side, and the air in the processing space is exhausted from the second intake port through the exhaust path inside the hollow cylindrical member. It is also possible to adopt a configuration in which it is introduced from the mouth into the exhaust chamber.

Further, a blade is installed near the nozzle means such that the upper part of the air pressing surface at the time of rotation is inclined forward from the lower part in the rotation direction, or the lower part of the air pressing surface at the time of rotation is provided in a branch pipe near the intake port. It is also possible to attach a wing that is inclined forward of the upper part in the rotational direction. Further, in the case of a configuration in which air is also taken in from the bottom of the hollow cylindrical portion, it is possible to attach a wing whose free end of the air pressing surface during rotation is inclined forward in the rotation direction near the exhaust port on the inner wall of the exhaust path. Is.

[0013]

Since the apparatus of the present invention is constructed as described above, the air sucked from the air supply chamber is swung down by the swirling air flow generating means around the side surface of the virtual cylinder having the virtual axis of the processing space as the central axis. And convert it into an air flow that
By sucking the air in the processing space from the intake port provided near the extension line of the virtual axis, the internal region surrounded by the descending swirling air flow is made negative pressure, and the tornado flow swirling and rising around the virtual axis is generated. It can be generated. As a result, without disposing a specific device in the processing space, gas and dust in the processing space are captured by the rising tornado flow without being diffused to the surroundings,
It is possible to exhaust from the exhaust chamber to the outside.

Further, as described above, the descending swirling airflow generating means is constituted by the hollow cylindrical member, the branch pipe line thereof, and the nozzle means, so that air is sucked from the air supply chamber to hollow the cylindrical member. It is possible to generate a descending air flow that is ejected downward through the nozzle section and the nozzle means via the branch section and the branch pipe line, and at that time, by rotating the hollow cylindrical member, the descending air flow is swirled, and the virtual axis is changed. It is possible to generate a downward swirling airflow along the side surface of the virtual cylinder that is the central axis.

Further, the intake chamber and the exhaust chamber are formed in the same air chamber via a partition wall, and the intake chamber is arranged above the exhaust chamber at this time, thereby saving the installation space. In addition, the rising tornado flow can be sucked into the exhaust chamber directly from the processing space.

Further, the structure of the apparatus can be simplified by forming an intake port for introducing the air in the processing space into the exhaust chamber around the outer periphery of the hollow cylindrical member and introducing it directly into the exhaust chamber. It is possible.

Alternatively, in addition to the intake port, a second intake port is formed at the bottom of the hollow cylindrical member on the processing space side, and the air in the processing space is exhausted from the second intake port inside the hollow cylindrical member. With the configuration in which the gas is introduced from the exhaust port into the exhaust chamber via the path, it is possible to stabilize the core of the rising tornado flow generated in the processing space.

Furthermore, by installing blades in the vicinity of the nozzle means, the upper part of the air pressing surface at the time of rotation being inclined forward from the lower part in the direction of rotation, a downward airflow is generated at the time of rotation,
It is possible to generate a stronger downward swirling airflow. On the contrary, by installing a blade whose lower part of the air pressing surface at the time of rotation inclines forward in the rotational direction from the upper part in the branch conduit near the intake port, an upward airflow is generated at the time of rotation,
It is possible to generate a stronger rising tornado flow. Alternatively, in the case of a configuration in which intake is also performed from the bottom of the hollow cylindrical portion, by attaching a blade whose free end of the air pressing surface during rotation is inclined forward in the rotation direction in the vicinity of the exhaust port of the inner wall of the exhaust path, The exhaust force from the exhaust path to the exhaust chamber can be further enhanced.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of an exhaust system constructed according to the present invention will be described below with reference to the accompanying drawings.

1 to 5 show an embodiment of an exhaust device constructed according to the present invention. As shown in FIG. 1, the exhaust device 1 includes an air chamber 2 that can be attached to a ceiling or the like of a space where exhaust processing is required, and the air chamber 2
And a rotating body 4 rotatably attached by a drive motor 3 in the center of the. The air chamber 2 is divided by a partition wall 5 into an upper air supply chamber 6 and a lower exhaust chamber 7. Outside air can be introduced into the air supply chamber 6 by the air supply fan 8, and the exhaust chamber 7
Can be exhausted by the exhaust fan 9. Further, an opening portion 10 is provided on the processing space side of the exhaust chamber 7, from which air in the processing space can be sucked.

The rotating body 4 is provided with an air supply header 18 made of a hollow cylindrical member, and the air supply header 18 is provided in the air chamber 2.
To the top wall 11 and the partition wall 5 of the bearing 1
It is attached via 2 and 13, and a joint 14
It can be directly connected to the drive motor 3 via, and by rotating the drive motor 3 in a direction indicated by an arrow 15, for example, the rotating body 4 itself can be rotated at a desired speed. Further, a plurality of air supply ports 16 are provided in the portion of the rotating body 4 exposed to the air supply chamber 6, and the air supply port 1
It is possible to introduce the air in the air supply chamber 6 into the cylindrical hollow portion 17 via 6.

The structure of the rotating body 4 can be easily understood with reference to FIGS. 2 and 3. As shown in the drawing, a main shaft 19 connectable to the drive motor 3 is attached to the top of the air supply header 18 of the rotating body 4 and the air supply header 1
The lower end of 8 is closed by a member 20. A plurality of branch pipes 21 and 22 are attached in a substantially horizontal direction in the circumferential direction from the vicinity of the lower end of the air supply header 18, and the ends of the branch pipes 21 and 22 are directed downward. Air supply nozzles 23, 24 that open are attached. With this configuration, the air supply chamber 6, the air supply port 16, the hollow portion 17, the branch pipe lines 21 and 22, and the air supply nozzle 23,
An air flow path to 24 is formed.

As shown in FIG. 1, the rotating shaft of the rotating body 4 is arranged so as to be aligned with an imaginary axis A which is set in a substantially vertical direction at substantially the center of the space where the exhaust treatment is carried out. With such a configuration, the air supply nozzles 23, 24 are rotated from the rotation shaft
Up the dust and toxic gas in the internal region of the virtual cylinder having a virtual bottom radius B substantially corresponding to the length up to the height and having a height C substantially corresponding to the length from the floor to the ceiling (or the exhaust device). It can be exhausted by a tornado flow.

Further, descending air flow generating means 25 as shown in FIG. 4 is attached to the air supply nozzles 23 and 24. In this descending airflow generating means 25, for example, the upper portion 25a of the air pressing surface when rotating in the rotation direction f is the lower portion 25 thereof.
The blades may be inclined so as to project to the front in the rotational direction with respect to b. With this configuration, as the air supply nozzles 23 and 24 are rotated in the rotation direction f, the air in front of the blades can be pushed down in the direction a, and the air is blown downward from the air outlets 26 of the air supply nozzles 23 and 24. It is possible to generate a stronger descending air flow in combination with the air flow.

Similarly, as shown in FIG. 3, ascending airflow generating means 27 and 28 are provided on the air supply header side of the branch pipe 21 and on the air supply nozzle side of the branch pipe 22, respectively.
It is attached via 9. The ascending airflow generating means 27 can be composed of, for example, a wing inclined so that the upper portion 27a of the air pressing surface during rotation with respect to the rotation direction f is inclined rearward of the lower portion 25b in the rotation direction. With this configuration, as the branch pipes 21, 22 are rotated in the rotation direction f, the air in front of the blades can be pushed upward in the direction b, and the rising tornado flow from the processing space can be more effectively and quickly. It can be introduced into the exhaust chamber 7.

Next, the exhaust device 1 configured as described above.
The process of generating a rising tornado flow will be described. First, by rotating the rotating body 4 by the drive motor 3, the supply airflow a supplied by the supply fan 8 is opened from the inside of the supply chamber 6 to the upper part of the supply header 18 of the rotating body 4. It enters into the hollow portion 17 through the air port 16 and becomes a downward flow b, further becomes a horizontal flow c that flows in the branch pipe lines 21 and 22, and is further discharged from the air supply nozzles 23 and 24 as a downward flow d into the exhaust treatment space. . Since the rotating body 4 continues to rotate during this time, a rotational force is also added to the downward flow d, and the downward swirling airflow d is blown out.

The descending swirling airflow d is generated in the lower region of the rotating body,
That is, the air in the virtual cylinder having the distance B from the central axis A to the nozzle as the bottom radius and the height C as the distance C from the floor to the device is forcibly swirled to make the inside of the rotation range negative pressure and the rising tornado. Flow e is generated. The generated tornado flow e rises to the upper part of the processing space, becomes an exhaust flow f that enters the exhaust chamber 7 through the intake port 10, and is exhausted to the outside by the exhaust fan 9.

At this time, as described with reference to FIGS. 4 and 5, the downward flow generating blade 2 for making the discharge flow d blown out from the air supply nozzles 23 and 24 into a more effective downward flow.
By providing 5 in the nozzle portion and ascending airflow generation blades 27, 28 for strongly rising the generated tornado flow in the branch conduit portion, a stronger tornado can be generated. Further, with such a configuration, even if an obstacle that interferes with the swirl flow generation is placed in the exhaust device, the generation of the tornado does not stop unlike the conventional case.

6 and 7 show yet another embodiment of the exhaust system constructed according to the present invention. The configuration and operation of this embodiment will be described below, but the same numbers are assigned to the components having the same functions as those of the previous embodiment, and detailed description thereof will be omitted.

In this embodiment, the exhaust passage 30 is formed in the hollow cylindrical portion of the rotating body 4 separately from the air supply passage 31, and the bottom closing member 20 (the first closing member 20 on the processing space side of the hollow cylindrical portion) is formed. 2) is provided with a second intake port 32 for intake of the rising tornado flow e from the processing space into the exhaust passage 30, and a plurality of exhaust ports 33 are provided in the portion corresponding to the exhaust chamber of the hollow cylindrical portion. Has been drilled. Furthermore, each exhaust port 33
An exhaust promotion vane 34 is attached to this so that the free end of the air pressing surface during rotation is inclined forward in the rotation direction.

With this configuration, the air supply nozzles 23, 24
The ascending tornado flow e formed by the descending swirling airflow d blown out from the air is sucked into the exhaust passage 30 in the hollow cylindrical portion as the second exhaust flow g in addition to the first exhaust flow f, and the exhaust promotion vanes are exhausted. The gas is exhausted from the exhaust port 33 to the exhaust chamber 7 as a third exhaust flow h. In this way, the rising tornado flow can be sucked also from the central portion of the rotating shaft, whereby the core of the generated tornado flow can be stabilized.

[0032]

As described above, according to the device of the present invention, the air sucked from the air supply chamber is converted from the descending swirling air flow generating means into the descending swirling air flow flowing around the side surface of the virtual cylinder surrounding the processing space. In addition, by sucking the air in the processing space from the intake port provided above the central axis of the virtual cylinder, the internal region surrounded by the descending swirling airflow becomes negative pressure, and the tornado swirls and rises around the virtual axis. It is possible to generate a flow. As a result, without disposing a specific device in the processing space, it is possible to capture the gas or dust in the processing space by the rising tornado flow without diffusing it to the surroundings and exhaust it from the exhaust chamber to the outside.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view of an embodiment of an exhaust device constructed according to the present invention.

FIG. 2 is a schematic cross-sectional view of a rotating body portion of an exhaust device configured according to the present invention.

FIG. 3 is a plan view of a rotary body portion of FIG.

FIG. 4 is an explanatory view of a descending airflow generating blade attached to the nozzle of the rotating body of FIG.

5 is an explanatory view of an updraft generating blade attached to a branch pipe of the rotating body of FIG. 2. FIG.

FIG. 6 is a schematic cross-sectional view of another embodiment of an exhaust device constructed according to the present invention.

7 is a cross-sectional view taken along the line AA of the apparatus of FIG.

FIG. 8 is a schematic view of a conventional draft chamber type exhaust device.

FIG. 9 is a schematic view of a conventional gate-column type exhaust device.

[Explanation of symbols]

d Downward swirling airflow e Rising tornado style 1 exhaust system 2 air chamber 3 drive motor 4 rotating body 6 Air supply chamber 7 exhaust chamber 8 Air supply fan 9 exhaust fan 10 air intake 16 Air supply port 17 Air supply path 18 Air supply header 21, 22 Branch pipe 23, 24 Air supply nozzle

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) F24F ^7/ 08-7/10

Claims (5)

(57) [Claims] 1. An air supply chamber provided above the exhaust processing space having a virtual axis and having an air supply means for introducing outside air, and a virtual axis of the processing space which is inhaled from the air supply chamber. A downward swirling airflow generating means for generating a downward swirling airflow around a side surface of a virtual cylinder having a central axis as a center axis, and a downward swirling airflow generating means installed above the processing space and provided near an upward extension line of the virtual axis. and the intake air in the treatment space than the air inlet Ri Do from an exhaust chamber having an exhaust means for exhausting to the outside, the downward swirl airflow generator
1 or 2 means for opening to said air supply chamber
Around the extension axis of the virtual axis with the above air supply port
A rotatable hollow cylindrical member, and the hollow cylindrical member
1 or 2 or more branched in the circumferential direction on the processing space side
A branch pipe and a vertical direction installed at the tip of the branch pipe
Nozzle means opening downward, and the air supply port
The air introduced into the hollow portion of the hollow cylindrical member is
From the nozzle means to the processing space via a branch pipe
A downward swirling airflow generation path is formed so that
Exhaust device, characterized in that 2. A wing that presses air forward in the rotation direction when the nozzle rotates is mounted near the nozzle means,
The exhaust system according to claim 1 , wherein an upper portion of the air pressing surface of the blade is inclined forward of the lower portion in the rotational direction. 3. A wing that presses air forward in the rotation direction when the branch pipeline is rotated is attached to the branch pipe near the intake port, and the lower part of the air pressing surface of the wing is inclined forward from the upper part in the rotation direction. Claim 1 or 2 characterized in that
Exhaust device according to. 4. A second intake port for introducing the air in the processing space into the exhaust chamber is formed at the processing space side bottom of the hollow cylindrical member, and the air in the processing space is the second
Is introduced into an exhaust passage formed as a separate passage from the descending swirling airflow generation passage inside the hollow cylindrical member from an intake opening of the hollow cylindrical member, and further through an exhaust opening communicating between the exhaust passage and the exhaust chamber. The exhaust device according to claim 1, wherein the exhaust device is introduced into the exhaust chamber. 5. A vane is attached to the inner wall of the exhaust passage near the exhaust port so as to press air forward in the rotational direction when the hollow cylindrical member rotates, and the free end of the air pressing surface of the vane is forward in the rotational direction. The exhaust system according to claim 4 , wherein the exhaust system is inclined.