KR20240021049A - Blower and exhaust system including same - Google Patents

Abstract

The technical idea of the present invention is to have a donut shape with a cavity formed in the center, an inner wall extending along the inner circumference of the donut shape and having a first gap through which air is discharged at the bottom, and an inner wall opposite to the inner wall and in the donut shape. a blower extending along the outer circumference and including an outer wall formed at the top with an air inlet through which air flows; a support portion configured to support the blower; and a supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air; wherein outside air does not flow into the lower surface of the cavity, and the inner wall of the blower is It provides a blowing device characterized in that it has a slope in which the horizontal cross-sectional area decreases as the vertical level increases.

Description

Blower and exhaust system including same}

The present invention relates to a blower and an exhaust system, and more specifically, to a blower that improves the efficiency of exhausting pollutants and an exhaust system including the same.

Generally, exhaust devices are installed in factories, homes, or restaurant kitchens that generate pollutants such as odors, harmful gases, smoke, and dust, and suck in air containing these pollutants (hereinafter referred to as pollutants) and discharge them to the outside. It is used for discharge purposes. However, as the distance between the pollutant source and the exhaust device increases, the exhaust efficiency of sucking in and discharging polluted air decreases rapidly, and even when the pollutant source is located in a wide open space, the exhaust efficiency of the exhaust device decreases.

The problem to be solved by the technical idea of the present invention is to provide a blower that prevents the spread of pollutants by forming an air curtain and vortex and moves the pollutants to the exhaust device, and an exhaust system including the same.

In addition, the problem to be solved by the technical idea of the present invention is not limited to the problems mentioned above, and other problems can be clearly understood by those skilled in the art from the description below.

The blower according to the present invention has a donut shape with a cavity formed in the center, an inner wall extending along the inner circumference of the donut shape and having a first gap at the bottom through which air is discharged, and an inner wall opposite to the inner wall and having the donut shape. a blower extending along the outer circumference and including an outer wall formed at the top with an air inlet through which air flows; a support portion configured to support the blower; and a supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air; wherein outside air does not flow into the lower surface of the cavity, and the inner wall of the blower is It is a blowing device characterized by having a slope in which the horizontal cross-sectional area decreases as the vertical level increases.

An exhaust system according to the present invention includes an exhaust device configured to discharge introduced substances to the outside; and a blowing device for moving contaminants to the exhaust device, wherein the blowing device has a donut shape with a cavity formed in the center, extends along the inner circumference of the donut shape, and moves in the horizontal direction as the vertical level increases. It includes an inner wall with a slope of decreasing cross-sectional area and a first gap through which air is discharged at the bottom, and an outer wall opposite to the inner wall, extending along an outer circumference in the donut shape, and having an air inlet at the top through which air flows in. and an outlet through which external air does not flow into the lower surface of the cavity; a support portion configured to support the blower; An exhaust system comprising a supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air.

An exhaust system according to the present invention includes an exhaust device configured to discharge introduced substances to the outside; and a blowing device for moving contaminants to the exhaust device, wherein the blowing device has a donut shape with a cavity formed in the center, extends along the inner circumference of the donut shape, and moves in the horizontal direction as the vertical level increases. It includes an inner wall with a slope of decreasing cross-sectional area and a first gap through which air is discharged at the bottom, and an outer wall opposite to the inner wall, extending along an outer circumference in the donut shape, and having an air inlet at the top through which air flows in. and an outlet through which external air does not flow into the lower surface of the cavity; a support portion configured to support the blower; A supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air, wherein the first gap is located at the same vertical height as the source of the pollutants, The speed of air discharged through the first gap is in the range of 10 m/s to 60 m/s, and the diameter of the outer wall of the air outlet is in the range of 0.9 to 1.2 times the diameter of the pollutant generating source. am.

The blower and exhaust system according to the technical idea of the present invention forms a vortex on top of the pollutant source and forms an air curtain around the pollutant source, so that the pollutants generated from the pollutant source do not spread to the outside and are easily exhausted. may enter the device.

1 is a cross-sectional view schematically showing an exhaust system according to an embodiment of the present invention.
Figure 2 is a plan view schematically showing a blowing device according to an embodiment of the present invention.
Figure 3 is an enlarged view of portion AA in the exhaust system of Figure 1.
FIG. 4 is a cross-sectional view for explaining the exhaust flow of the exhaust system of FIG. 1.
Figure 5 is a cross-sectional view schematically showing an exhaust system according to an embodiment of the present invention.
Figure 6 is an enlarged view of the BB portion of the exhaust system of Figure 5.
Figure 7 is a plan view schematically showing a blowing device according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and duplicate descriptions thereof are omitted.

1 is a cross-sectional view schematically showing an exhaust system according to an embodiment of the present invention. Figure 2 is a plan view schematically showing a blowing device according to an embodiment of the present invention.

Referring to FIGS. 1 and 2 , the exhaust system 10 may include a blower 200 and an exhaust device 300 . The blower 200 may move pollutants generated from the pollutant generator 100 to the exhaust device 300 .

According to exemplary embodiments, the pollutant generator 100 is a container capable of containing liquid or gas, and may have a shape in which one side, for example, the top side, is open. According to exemplary embodiments, the pollutant generating source 100 may be a chamber, pot, or structure in the form of a chamber. Pollutants may be generated from the pollutant generator 100 due to a chemical reaction or the like. In some embodiments, the contaminants may include harmful gases generated in the process, for example, gas containing heavy metals generated in a semiconductor plating process, cooking fumes generated when cooking food, etc. However, it is not limited to this.

The blower 200 may surround the pollutant generating source 100 in the horizontal direction. The blower 200 may extend along a side, for example, a side perpendicular to the open side of the pollutant generating source 100 . That is, the blower 200 may be positioned to surround the side of the pollutant generating source 100.

When the open surface of the pollutant generator 100 is referred to as the upper surface, the X-axis direction and Y-axis direction represent directions parallel to the upper or lower surface of the pollutant generator 100, and may be in directions perpendicular to each other. The Z-axis direction may represent a direction perpendicular to the upper or lower surface of the pollutant generating source 100. In other words, the Z-axis direction may be perpendicular to the X-Y plane.

Additionally, in the following drawings, the first horizontal direction, the second horizontal direction, and the vertical direction may be understood as follows. The first horizontal direction can be understood as the X-axis direction, the second horizontal direction can be understood as the Y-axis direction, and the vertical direction can be understood as the Z-axis direction.

The blowing device 200 may include an air blower 210, a support part 230, and a supply part 250. The blower 210 may have a donut shape with a cavity 290 formed in the center. The vent 210 may have an annular shape with an empty center when viewed in the vertical direction (Z). The blower 210 may have an inner wall 211 extending along the circumference of the inner circle in the donut shape, and an outer wall 213 extending along the outer circumference.

The outer wall 213 may have an air inlet 219 at the top through which air flows in, and the inner wall 211 may have a first gap 215 at the bottom through which air introduced from the air inlet 219 is discharged. ) can be formed. The farthest distance between the outer wall 213 and the inner wall 211 may be 60 mm, and the height of the blower 210 may be 200 mm, but is not limited thereto. The farthest distance between the outer wall 213 and the inner wall 211 It is sufficient if the ratio of the height of the air outlet 210 corresponds to a ratio of 3:10. The diameter of the outer wall 213 may be in the range of 1 m to 2 m. According to exemplary embodiments, the diameter of the outer wall 213 may be in the range of 0.9 to 1.1 times the diameter of the pollutant generating source 100.

The shape of the vent 210 and the flow of air passing through the vent 210 will be described in detail with reference to FIGS. 3 and 4.

The support portion 230 may be configured to support the vent 210. According to exemplary embodiments, the support part 230 may be disposed on the lower surface of the blower 210. The support portion 230 may support the lower surface of the tuyere 210 on the lower surface of the tuyere 210, but is not limited thereto. The support portion 230 may support the tuyere 210 by contacting the side of the tuyere 210. You can. The blower 210 can be fixed at a certain height by the support part 230.

According to exemplary embodiments, the vertical direction (Z) height of the support portion 230 is 20% of the radius of the pollutant generator 100, based on the vertical direction (Z) height of the pollutant generator 100. There may be deviations. For example, when the radius of the contaminant generating source 100 is 1 m, the height of the support part 230 may be located in a range of -20 cm to +20 cm than the height of the contaminant generating source 100.

In some embodiments, the first height L1 of the support part 230 may be equal to the height of the pollutant generating source. The upper surface of the support part 230 may be located on the same plane as the upper surface of the pollutant generating source 100. That is, the upper surface of the support part 230 may be located at the same vertical level as the upper surface of the pollutant generating source 100. The first gap 215 of the blower 210 located on the support part 230 may be located on the upper surface of the support part 230. Accordingly, the pollutants generated from the pollutant generating source 100 and the first gap 215 of the blower 210 supported by the support portion 230 are located at the same vertical level, so that the exhaust device 300 Contaminants can be easily moved.

In some embodiments, the support portion 230 may have a donut shape with a cavity 290 formed in the center. In some embodiments, the support portion 230 may have a cylindrical shape extending in the vertical direction (Z). In the above embodiments, when the support part 230 has a donut shape with a cavity 290 formed in the center, the contaminant generating source 100 is accommodated in the cavity 290, and the support part 230 and the contaminant generating source ( 100) The lower surface of the cavity 290 may be blocked by the ground or a holder. Accordingly, external air may not flow into the lower surface of the cavity 290. That is, air may not flow in from the outside through the lower surface of the cavity 290. Additionally, in the above embodiments, when the support part 230 has a cylindrical shape extending in the vertical direction (Z), the pollutant generating source 100 is disposed on the upper surface of the support part 230, and the blower 210 Since is arranged to surround the pollutant generating source 100 in the horizontal direction (X, Y), the lower surface of the cavity 290 of the blower 210 may be blocked by the upper surface of the support portion 230. Accordingly, external air may not flow in from the lower surface of the cavity 290.

According to example embodiments, the support part 230 may include a height adjustment member configured to adjust the height along the vertical direction (Z). As the vertical height of the support part 230 is adjusted, the vertical height of the blower 210 supported by the support part 230 can also be adjusted. If the height of the support part 230 is reduced by the height adjustment member, the height of the blower 210 may also decrease, and thus the position of the first gap 215 formed in the inner wall 211 of the blower 210 may be reduced. Ultimately, the position of the air discharged to the outside from the blower 210 can be adjusted by the height adjustment member of the support part 230.

The supply unit 250 may be configured to suck air from the outside and supply it to the blower 210 by adjusting the speed of the sucked air. According to exemplary embodiments, the supply unit 250 may provide air to the air inlet 219 of the outlet 210. The supply unit 250 may include an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air. According to exemplary embodiments, the air supply member may include, but is not limited to, a blower, fan, process air, compressor, etc., and may be a device capable of sucking in external air. This is enough. According to exemplary embodiments, the air volume control member is a device that controls the flow rate of the sucked air through the flow rate, and may include, for example, a damper, a throttle valve, etc., but is limited thereto. It doesn't work. The supply unit 250 may provide air having a target speed to the air inlet 219 of the blower 210 through the air supply member and the air volume control member.

The exhaust device 300 may be configured to suck in air containing pollutants and discharge the sucked pollutants to the outside. Pollutants may be sucked into the exhaust device 300 by natural negative pressure, and may also be forced into the exhaust device 300 by an exhaust fan installed on the exhaust device 300, such as a sirocco fan. It could be. According to exemplary embodiments, the exhaust device 300 includes a hood with an opening for sucking in pollutants, a duct for transporting the sucked pollutants, a fan, an air purifying device, etc. It may include, but is not limited to this.

The exhaust device 300 may be arranged to face the open surface of the pollutant generating source 100. According to exemplary embodiments, when the open surface of the pollutant generating source 100 is the upper surface, the exhaust device 300 may be positioned spaced apart from the upper surface of the exhaust device 300 in the vertical direction (Z). .

Figure 3 is an enlarged view of portion AA in the exhaust system of Figure 1. FIG. 4 is a cross-sectional view for explaining the exhaust flow of the exhaust system of FIG. 1. Hereinafter, content that overlaps with the content described with reference to FIGS. 1 and 2 will be omitted and the description will focus on the shape of the air outlet 210 and the air flow.

Referring to Figures 3 and 4, the blower 210 may include an inner wall 211 and an outer wall 213, and a first gap 215 is formed in the inner wall 211, and a first gap 215 is formed in the outer wall 213. An air inlet 219 may be formed.

The inner wall 211 may have an inclination in which the area of the horizontal cross-sectional area decreases as the level in the vertical direction (Z) increases. The inner wall 211 may have a shape that approaches the pollutant generating source 100 as the level in the vertical direction (Z) decreases. At this time, the upper end of the inner wall 211 may have a straight shape extending in the vertical direction (Z).

A first gap 215 may be formed at the bottom of the inner wall 211. The first gap 215 may be a gap formed when the inner wall 211 and the lower surface of the blower 210 do not meet. The width of the first gap 215 may range from 0.5 mm to 2 mm. When the width of the first gap 215 becomes larger than 2 mm, the flow rate of air discharged through the blower 210 increases, allowing contaminants to spread outside the air curtain, which will be described later.

The outer wall 213 faces the inner wall 211 and may have a shape extending straight in the vertical direction (Z). An air inlet 219 may be formed at the top of the outer wall 213. According to exemplary embodiments, the lower surface of the tuyere 210 may have a U-shape.

The air flowing into the air inlet 219 of the outlet 210 from the supply unit (see FIG. 1, 250) descends along the outer wall 213 and may gradually rise from the U-shaped lower surface. The raised air may be discharged to the outside along the first gap 215 formed in the inner wall 211. Some of the air discharged through the first gap 215 may rise along the outer surface of the inner wall 211 according to the Coanda effect. At this time, since the inner wall 211 has a slope in which the horizontal cross-sectional area decreases as the vertical level increases, the air can move away from the pollutant generating source 100 along the slope. Another part of the discharged air may rise straight in the vertical direction (Z) and another part may move in a direction disposed at the pollutant generating source 100. At this time, the speed of air rising along the surface of the inner wall 211 becomes fastest, and the air pressure becomes lower than the upper part of the pollutant generating source 100. Accordingly, contaminants at the top of the contaminant generating source 100 may move toward the inner wall 211. In addition, the speed of the air discharged through the first gap 215 decreases as it moves away from the pollutant generator 100 in the vertical direction (Z), forming a low pressure in the upper part of the pollutant generator 100, and the exhaust device ( The closer it gets to 300), the more high pressure can form. Accordingly, a portion of the air rising along the inner wall 211 of the vent 210 may descend toward the center of the pollutant generating source 100 again.

Ultimately, at the top of the pollutant generator 100, the air moves as indicated by the arrow shown in part P2 of FIG. 4 and a vortex may be formed, and the pollutant rises in the central part of the pollutant generator 100 due to the vortex. This prevents the contaminants from moving toward the air curtain.

When the air reaches the top of the inner wall 211, the top of the inner wall 211 has a straight shape extending in the vertical direction (Z), so the air can rise straight in the vertical direction (Z). . That is, an airflow in which air rises straight may be formed in the P1 portion of FIG. 4. An air curtain extending in a direction (Z) perpendicular to the air flow may be formed. The air curtain may be an air film generated when air discharged from the outlet 210 is sucked into the exhaust device 300. The air curtain can prevent pollutants generated from the pollutant generator 100 from spreading outside the blower 200.

Ultimately, due to the above-described shape of the blower 210, an air curtain may be formed along the inner wall 211 of the blower 210, and a vortex may be formed at the upper part of the pollutant generating source 100.

v1, which is the speed of air discharged to the outside through the first gap 215, may be in the range of 10 m/s to 60 m/s. When the discharged air is discharged at a speed within the above range, the speed of the pollutants floating on the pollutant generating source 100 may be higher than the reference speed. The reference speed may correspond to 0.5 m/s if the pollutant is a gas and 1.2 m/s if the pollutant is a particle.

Figure 5 is a cross-sectional view schematically showing an exhaust system according to an embodiment of the present invention. Figure 6 is an enlarged view of the BB portion of the exhaust system of Figure 5. Hereinafter, overlapping content between the exhaust system 10 of FIG. 1 and the exhaust system 11 of FIG. 5 will be omitted and the differences will be mainly explained.

5 and 6, the exhaust system 11 may include a blower 201 and an exhauster 300, and the blower 201 includes a blower 210, a support portion 230, and a supply portion. It may include (250).

According to exemplary embodiments, the supply unit 250 may be formed within the air outlet 210. The supply unit 250 may include an air supply member 251, an air volume control member 253, and a supply passage 255. The air supply member 251, the air volume control member 253, and the supply passage 255 are formed within the support portion 230. According to exemplary embodiments, the air supply member 251 is in contact with the side surface of the support portion 230. It can be formed to do so. The air volume control member 253 may be connected to the air supply member 251, and the speed of external air sucked through the air supply member 251 may be adjusted as it passes through the air volume control member 253. The air that has passed through the air volume control member 253 may be provided to the air inlet 219 of the outlet 210 along the supply passage 255.

Figure 7 is a plan view schematically showing a blowing device according to an embodiment of the present invention. Hereinafter, overlapping content between the blower 200 of FIG. 2 and the blower 202 of FIG. 7 will be omitted and the differences will be mainly explained.

Referring to FIG. 7 , the blowing device 202 may include an air blower 210, a support part 230, and a supply part 250. According to exemplary embodiments, the blower 202 may be separated and combined into a first part C1 and a second part C2. The first part C1 and the second part C2 may be separated and combined in the horizontal direction (X, Y). That is, the blower 202 can be separated and combined at a cross section cut in the vertical direction (Z). The separation and coupling means may be mechanical means, for example, screws, magnets, hooks, etc. may be used.

As the blowing device 202 can be separated and combined, it is easy to install the blowing device 202 around the pollutant generating source 100, and the blowing device 202 can also be installed on the pollutant generating source 100 having different sizes. can be applied.

In FIG. 7, the blower 202 is shown as having a structure in which two parts C1 and C2 are separated and combined, but it is not limited to this and may have a structure in which three or more parts can be separated and combined.

As above, exemplary embodiments have been disclosed in the drawings and specification. In this specification, embodiments have been described using specific terms, but this is only used for the purpose of explaining the technical idea of the present disclosure and is not used to limit the meaning or scope of the present disclosure described in the claims. Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true technical protection scope of the present disclosure should be determined by the technical spirit of the attached claims.

100: pollutant source, 200: blower, 210: blower, 211: inner wall, 213: outer wall, 215: first gap, 219: air inlet, 230: support, 250: supply, 251: air supply member, 253: Air volume control member, 255: supply passage, 290: cavity, 300: exhaust device,

Claims (10)

An inner wall having a donut shape with a cavity formed in the center, extending along the inner circumference of the donut shape and having a first gap through which air is discharged at the bottom, and an inner wall opposite to the inner wall and extending along an outer circumference of the donut shape and having an upper end. an air outlet including an outer wall formed with an air inlet through which air flows;
a support portion configured to support the blower; and
A supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air;
Outside air does not flow into the lower surface of the cavity,
The inner wall of the blower is a blowing device characterized in that the horizontal cross-sectional area decreases as the vertical level increases. According to paragraph 1,
The first gap extends along the inner wall of the blower and has an annular shape. According to paragraph 1,
A blowing device, characterized in that the vertical height of the support part is adjusted. According to paragraph 1,
A blowing device characterized in that the speed of air discharged to the outside through the first gap is in the range of 10 m/s to 60 m/s. According to paragraph 1,
A blowing device, characterized in that the blower, the support part, and the supply part can be separated and combined into a first part and a second part. An exhaust device configured to discharge the introduced substances to the outside; and
Including a blowing device that moves pollutants to the exhaust device,
The blower device,
An inner wall having a donut shape with a cavity formed in the center, extending along the inner circumference of the donut shape, having an inclination in which the horizontal cross-sectional area decreases as the vertical level increases, and a first gap through which air is discharged is formed at the bottom, and an air outlet opposite to the inner wall, extending along an outer circumference in the donut shape, including an outer wall with an air inlet formed at an upper end through which air flows in, and through which external air does not flow into the lower surface of the cavity;
a support portion configured to support the blower; and
An exhaust system comprising: a supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust a speed of the sucked air. According to clause 6,
The first gap is located at the same vertical level as the upper surface of the pollutant source where the pollutants are generated. According to clause 6,
An exhaust system, characterized in that the supply part is formed within the support part. According to clause 6,
The first gap has an annular shape extending along the perimeter of the inner wall,
An exhaust system, characterized in that the diameter of the outer wall is in the range of 0.9 to 1.2 times the diameter of the pollutant source from which the pollutant is generated. An exhaust device configured to discharge the introduced substances to the outside; and
Including a blowing device that moves pollutants to the exhaust device,
The blower device,
An inner wall having a donut shape with a cavity formed in the center, extending along the inner circumference of the donut shape, having an inclination in which the horizontal cross-sectional area decreases as the vertical level increases, and a first gap through which air is discharged is formed at the bottom, and an air outlet opposite to the inner wall, extending along an outer circumference in the donut shape, including an outer wall with an air inlet formed at an upper end through which air flows in, and through which external air does not flow into the lower surface of the cavity;
a support portion configured to support the blower; and
It includes a supply unit including an air supply member configured to suck in external air and an air volume control member configured to adjust the speed of the sucked air,
The first gap is located at the same vertical height as the upper surface of the pollutant source where the pollutant is generated,
The speed of air discharged through the first gap is in the range of 10 m/s to 60 m/s,
An exhaust system, characterized in that the diameter of the outer wall of the air outlet is in the range of 0.9 to 1.2 times the diameter of the pollutant generating source.

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