KR102080503B1 - Ventilator having a damper - Google Patents

Abstract

The present invention relates to a damper-embedded fan, comprising: a housing in which an air flow chamber is formed, and an air discharge port communicating with the air flow chamber is provided; An impeller rotatably connected to a rotating shaft of a motor and embedded in the housing; And a backflow prevention damper for opening and closing the air outlet. According to the present invention, since each component in the fan can be disassembled by a simple detachable method, the user directly directly disassembles each element in the fan sequentially to solve problems occurring in each element or to facilitate maintenance such as cleaning. Can be done.

Description

Ventilator with damper built-in {VENTILATOR HAVING A DAMPER}

The present invention relates to a damper-embedded fan, and more particularly, a user can easily perform repair or repair, or can easily perform maintenance such as cleaning through a detachable method for facilitating coupling and disassembly of components in the fan. It relates to a damper built-in fan provided in a structure capable of.

In general, buildings such as homes and offices are provided with ventilation facilities to maintain a comfortable indoor environment by forcibly exhausting carbon dioxide, polluted air, and odors accumulated in the interior space to the outside.

The ventilation system is mainly installed in the form of a buried upper part of the ceiling finish of the building, and has a structure in which each interior of the building communicates through a duct unit (for example, a flexible pipe and a diffuser).

Such a prior art related to the ventilation facility has been disclosed in the "slide assembly ventilator" of Publication No. 10-2017-0064824 (June 12, 2017). That is, the ventilation facility is a device for purifying intake and exhaust, air conditioning or air in a building, and may be provided as a device such as the conventional fan. Such a fan is used for inhaling and discharging smoke and odors in each room of a bathroom, a toilet, a dressing room, or a kitchen of a building.

As such, the conventional ventilator is actually difficult to combine and disassemble the respective components individually because the components provided therein are coupled and disassembled by bolting or other complicated fastening methods. That is, when a conventional ventilator causes a problem in each component, or requires maintenance such as cleaning, there is a cumbersome problem in use that can only be resolved by requesting a specialist or a complicated disassembly process.

Moreover, it is preferable that the conventional ventilator is provided with a damper for preventing backflow of exhausted carbon dioxide, polluted air, and odors. Such a damper is typically installed on the exhaust port path as a separate part from the outside of the fan, or detachable from the outside due to the difficulty of combining and disassembling the respective components in the fan as described above. For this reason, when a conventional blower has a problem with a connected damper or requires maintenance such as cleaning, the damper is only damped when a part of the ceiling finishing material of a buried building is dismantled or the fan itself is separated from the dismantled ceiling finishing material. Since it can be decomposed from the ventilator, there was a problem in use that can only be solved by a professional.

"Slide-assembled ventilator" of Publication No. 10-2017-0064824 (Jun. 12, 2017)

The present invention is to solve the above problems, by applying a detachable structure that can easily detach the respective components in the fan to solve the problem caused by the user to directly disassemble the respective components in sequence It is an object of the present invention to provide a damper built-in fan that can perform maintenance such as cleaning or cleaning.

In particular, when the non-return damper is mounted on the air outlet of the fan, another object of the present invention is to provide a damper-embedded fan having a structure capable of detachably mounting the non-return damper in the inside of the ventilator.

In addition, the rotation of the non-return damper may be limited by defining a coupling position of the non-return damper mounted through a coupling groove and a coupling protrusion formed on an outer surface of the non-return damper and an inner surface of the air outlet. Another object is to provide a damper-embedded fan.

In addition, the air outlet is provided in the form of a tube extending continuously in a circular cross-sectional shape connected to the normal circular duct in the cross-sectional shape of the square close to the air discharge form by the impeller guides the air sent by the impeller by the vortex Another object of the present invention is to provide a damper-embedded fan capable of smoothly discharging to the outside of the fan with minimal noise.

In addition, it is another object to provide a damper-embedded fan that can be easily attached to the impeller by the magnetic coupling method through a magnet provided at the connection portion of the impeller and the motor rotation shaft.

In order to achieve the above object, a damper-embedded fan according to the present invention includes: a housing in which an air flow chamber is formed and an air outlet communicating with the air flow chamber is provided; An impeller rotatably connected to a rotating shaft of a motor and embedded in the housing; And a backflow prevention damper for opening and closing the air outlet.

Such a backflow prevention damper may be configured to be detachably mounted to the air outlet inside the housing.

In this case, the non-return damper may be configured to be combined with the air outlet by being provided in a shape corresponding to the inner shape of the air outlet.

In addition, to guide the coupling and disassembly direction in the detachable direction of the non-return damper, the outer surface of the anti-return damper and the inner surface of the air outlet in contact with each other in order to limit the coupling position of the combined anti-backflow damper Coupling grooves formed on the surface; And a coupling protrusion.

The impeller described above may be configured as a sirocco fan provided in a cylindrical fan shape and blowing air in a tangential direction during rotation.

In addition, the air outlet, it may be configured in the form of a tube extending from a rectangular cross-sectional shape to a circular cross-sectional shape so that the air sent by the impeller is smoothly discharged.

On the other hand, the non-return damper may be configured to have a conformal outer shape corresponding to the circular cross-sectional shape of the air outlet to be fitted to match the circular cross-sectional shape portion.

And, the impeller detachable means for detachably coupling the impeller and the motor shaft; may further include.

The impeller attachment and detachment means may further include a magnet provided at a connection portion between the impeller and the motor rotation shaft.

On the other hand, the damper built-in fan according to the present invention, the air flow chamber is formed therein, the housing which is provided with an air outlet communicating with the air flow chamber; And an impeller rotatably connected to a rotation shaft of a motor, the impeller being detachably coupled to the impeller and the motor rotation shaft, wherein the motor rotation shaft is made of a magnetic material magnetically coupled to a magnet. The impeller has a connecting groove into which the rotating shaft can be inserted and a magnet provided inside the connecting groove, and the connecting groove is inserted into the rotating shaft, which is partially chamfered. The locking jaw has a locking jaw in a rotational direction of the rotary shaft, and the locking jaw may have a structure for forming a play with respect to the rotational direction of the rotating shaft inserted into the connection groove.

At this time, the axis of rotation has a shape of a cross-section perpendicular to the axial direction has a shape of a circle chamfered part of the arc, the shape of the cross-section of at least a portion of the connection groove corresponding to the axis of rotation having a circle cross-section chamfered part of the arc A portion of the chamfered area may be occupied by the cross section of the locking jaw and may have a shape close to a circle surrounding the outer edge of the rotation shaft.

In this case, the locking jaw may be a slope for guiding the insertion of the rotary shaft from the insertion direction of the rotary shaft to the inner direction of the connecting groove.

According to the damper-embedded fan according to the present invention, since each component in the fan can be disassembled by a simple detachable method, the user directly directly disassembles each component in the fan sequentially and solves or cleans a problem occurring in each component. Etc. Maintenance can be performed easily.

Moreover, unlike the existing ones, users can perform the above tasks directly without having to use an expert, thereby reducing the need for an expert to solve a problem or perform maintenance such as cleaning. Can reduce the cost.

In addition, the non-return damper mounted on the air outlet of the fan is easily detachable from the inside of the fan, unlike the conventional one, so that the fan can be easily mounted even after installation on the ceiling finish of the building. That is, the backflow damper can also be disassembled inside the fan, so if a problem occurs in the backflow damper or needs maintenance, such as cleaning, the user can easily perform the above-described operation directly.

Moreover, the backflow prevention damper is prevented from rotating because it restricts the engagement position of the backflow prevention damper mounted through the engaging groove and the engaging projection formed on the mutually abutting surface of the outer surface of the backflow prevention damper and the inner surface of the air outlet. Since the air outlet is opened and closed in the same form, carbon dioxide, contaminated air, and odor accumulated in the space inside the building can be efficiently exhausted to the outside of the fan.

In addition, the air outlet is provided in the form of a tube extending from a rectangular cross section to a circular cross section so that the air sent by the impeller, that is, carbon dioxide, contaminated air, and odor accumulated in the space inside the building does not hit the inner wall of the fan. It can be guided and exhausted to the outside of the fan smoothly. That is, the air outlet is provided with the hydrodynamic structure as described above, it is possible to further improve the exhaust efficiency.

In addition, the impeller may be detachably mounted to the motor shaft by a magnetic coupling method through a magnet provided at a connection portion between the impeller and the motor shaft. That is, since the impeller can also be disassembled inside the fan, when a problem occurs in the impeller or needs maintenance such as cleaning, the user can easily perform the above-described operation directly.

Further, the locking jaw inside the connection groove of the impeller rotated by the rotation of the motor shaft is configured to occupy only a portion of the chamfered area of the chamfered rotation shaft, or in addition, the locking jaw is formed with respect to the insertion direction of the rotation shaft. The coupling of the impeller to the rotating shaft can be more easily performed.

1 is a view showing the overall state of a damper built-in fan according to the present invention.
FIG. 2 is a diagram illustrating an exploded state of FIG. 1.
3 is a view showing a cross-sectional view 'A-A' of FIG.
4 is a view illustrating an exploded state of FIG. 3.
5 is a view showing an embodiment of a coupling structure of the air outlet and the non-return damper.
6 is a cross-sectional view illustrating a coupling structure of a rotation shaft and a connection groove of a motor.
7 is a cross-sectional view showing the shape of the locking step in the connection groove.

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

Unless otherwise defined, all terms in the specification are the same as the general meaning of the terms understood by those skilled in the art, and if the terms used herein conflict with the general meaning of the terms Is in accordance with the definitions used herein.

On the other hand, the configuration or system of the device to be described below is not intended to limit the scope of the present invention, but to describe the embodiments of the present invention, the same reference numerals used throughout the specification are the same components Indicates.

The damper-embedded fan 100 according to the present invention forms an air flow chamber 111 therein, and is provided with a tubular part 200 having an air outlet 115 communicating with the air flow chamber 111. 110; An impeller 130 rotatably connected to the rotation shaft 121 of the motor 120 and embedded in the housing 110; And a backflow prevention damper 150 that opens and closes the air outlet.

The housing 110 may be provided in the form of a box forming an inner space as shown in FIGS. 1 to 4. In detail, the housing 110 is provided with an inlet 113 open toward the inside of the building, and an air outlet 115 open toward the outside of the building.

Here, the housing 110 forms the air flow chamber 111 in the above-described internal space as shown in FIGS. 3 and 4. Such, the air flow chamber 111 is typically formed in a cylindrical shape inside, it is provided with an impeller 130 to be described later inside. As such, in the air flow chamber 111, back pressure is generated in which air generated while the impeller 130 provided is rotated is compressed. That is, carbon dioxide, polluted air, and odors accumulated in the building interior space sucked into the air flow chamber 111 by the impeller 130 (hereinafter, referred to as “polluted air”) are the air flow chamber 111 through the back pressure. While being guided to the inner side of the) flows to the air outlet 115 to be described later is exhausted.

Inlet 113 is provided in the lower portion of the housing 110, circular. It may be provided in a variety of cross-sectional shape, such as a square or polygon, in the present invention is provided in a cross-sectional shape of a square. The inlet 113 serves not only a passage through which the above-described components enter and exit the internal space of the housing 110, but also serves as an inlet through which contaminated air flows into the air flow chamber 111 described above.

The air outlet 115 is provided on the side of the housing 110, but may be provided in a variety of cross-sectional shapes, such as circular, square or polygonal, in the present invention is provided in a rectangular cross-sectional shape. The tubular part 200 serves as a passage for exhausting the contaminated air sucked in the air flow chamber 111 to the outside of the housing 110.

Here, the tubular portion 200 has been described as having a rectangular cross-sectional shape, but to form a shape corresponding to the cross-sectional shape of the duct or flexible tube coupled thereto, as shown in Figs. 1 to 5 from the rectangular cross-sectional shape It is possible to achieve a structure that is converted into a circular cross-sectional shape. In detail, the structure of the tubular part 200 is different from the structure of the tubular part 200 provided in the existing ventilator (a structure that forms a circular cross-sectional shape on an inner wall that blocks a portion of the rectangular cross-sectional shape). It may be formed in a tubular hydrodynamic structure inclined extending from the rectangular cross-sectional shape to the circular cross-sectional shape so as not to block.

Accordingly, the tubular part 200 guides and exhausts the polluted air sucked into the air flow chamber 111 from a rectangular cross-sectional shape to a circular cross-sectional shape. That is, since the tubular portion 200 does not form an inner wall that partially blocks the rectangular cross-sectional shape, the tubular part 200 may provide an effect of preventing the occurrence of noise or eddy current caused by the contaminated air hitting the inner wall. Furthermore, since the tubular portion 200 does not reduce the back pressure of the polluted air exhausted through it according to the above-described structure, the polluted air maintains the back pressure capable of sufficiently pushing the blocking plate of the backflow prevention damper 150 which will be described later. It may also provide an effect.

 For example, the tubular part 200 may be integrally formed by protruding from the side of the housing 110, and may be formed as a member having a separate tubular shape as in an embodiment, and may be detachably mounted to the outside of the housing 110. It may be.

On the other hand, the housing 110 may be provided with a panel unit 160 for partitioning the internal space as shown in Figs. The panel 160 is formed in a plate-like structure in which an air inlet 161 having a hole is formed inside, as shown in FIG. 2, and an impeller (to be described later) provided in the air flow chamber 111 described above. In order to compress the air generated by the 130 in the air flow chamber 111, as shown in FIG. 3, the air flow chamber 111 may be provided inside the housing 110 in a state of blocking the lower portion. For example, the panel 160 may be integrally formed to protrude from the inner surface of the housing 110, and may be provided as a member having a separate plate shape and detachably mounted inside the housing 110.

Here, when the panel 160 is provided as a separate member as described above, in order to detachably mount the panel 160 inside the housing 110, various detachment such as a bolting method, a fastening method or a magnetic coupling method. Although the method may be used, the panel unit 160 may be easily mounted in the housing 110 by using the magnetic coupling method. More specifically, as the magnet 170 is provided at the connection portion between the panel 160 and the inner side of the housing 110, the panel 160 may be magnetically coupled to the inside of the housing 110.

Accordingly, the panel 160 may be detachably mounted inside the housing 110. That is, the panel 160 may be disassembled as well as mounted inside the housing 110.

Therefore, when a problem occurs in the panel unit itself itself or maintenance is required, such as cleaning, the user can easily disassemble the panel unit 160 inside the housing 110 to easily perform the above-described operation. Unlike existing methods, it is possible to reduce the hassle of having to solve them through experts, which is convenient to use, and it can also effectively reduce the time or cost required by the existing methods.

Impeller 130 may be provided in the form of a cylindrical fan, as shown in Figures 2 to 4, preferably may be composed of a sirocco fan.

As shown in FIG. 3, the impeller 130 may have a connection groove 131 recessed in an inner center thereof. The rotation groove 121 of the motor 120 provided in the housing 110 may be inserted into and connected to the connection groove 131. A more specific configuration example of the connection groove 131 and the rotation shaft 121 will be described later in more detail.

Accordingly, the impeller 130 may be rotatably connected to the rotation shaft 121 of the motor 120, and may be embedded in the air flow chamber 111 of the housing 110 in which the rotation shaft 121 of the motor 120 is disposed. have. That is, the impeller 130 rotates by being driven by the driving force of the motor 120, and blows air toward the inner side of the air flow chamber 111 in a tangential direction during rotation.

Meanwhile, the impeller 130 may further include a detachable means for detachably coupling the impeller 130 to the rotation shaft 121 of the motor 120.

The impeller 130 detachable means may use various detachable methods, such as a bolting method, a fastening method or a magnetic coupling method, but in the present invention, the impeller 130 is easily mounted on the rotating shaft 121 of the motor 120 by using a magnetic coupling method. Can be combined. In more detail, the impeller 130 may be magnetically coupled to the motor 120 rotating shaft 121 by providing a magnet 170 at a connection portion between the impeller 130 and the motor 120 rotating shaft 121. At this time, the magnet 170 may be provided in the impeller 130, or may be configured as a magnet 170 having a magnetic axis of rotation (121) itself, preferably as shown in Figure 3 impeller 130 It is embedded in the space provided separately in the lower connection groove 131.

Accordingly, the impeller 130 may be detachably coupled inside the housing 110 by the impeller 130 detachable means using a magnetic coupling method. That is, the impeller 130 may not only be coupled to the rotation shaft 121 of the motor 120 inside the housing 110 but may also be disassembled.

Therefore, when a problem occurs in the impeller 130 itself or needs maintenance, such as cleaning, the user can directly perform the above-described operation by disassembling the impeller 130 directly inside the housing 110. Unlike the existing method, it is convenient to use because it can reduce the trouble to solve by the experts, and it can also effectively reduce the time or cost required by the existing method.

In addition, as shown in Figure 6 to 7 for the easy coupling operation of the rotating shaft 121 and the impeller 130 connecting groove 131 of the motor 120, the rotating shaft 121 and the connecting groove 131 has a unique structure It can have

That is, in order to allow the impeller 130 to rotate together in the rotational direction of the rotation shaft 121, as is commonly known, the rotation shaft 121 has a form in which a portion of an outer surface of a cylindrical shape is chamfered, and the rotation shaft 121 is rotated. The insertion groove 131 to be inserted may be formed in a hole shape in conformity with the chamfered shape, in this case, if the cross-sectional shape inside the connection groove 131 is formed only the same as the cross-sectional shape of the rotary shaft 121, the rotary shaft Inserting the 121 into the connection groove 131 may be difficult.

In order to solve this problem, it is preferable that the locking step 131 inside the connection groove 131 is not formed to occupy the entire chamfered area, but is formed to occupy only a portion thereof as shown in FIG. 6. That is, as shown, when the chamfered region of the rotation shaft 121 has a semicircle shape, the cross-sectional shape of the locking jaw 132 may be formed to have a fan-shaped cross section having an internal angle of 90 °, rather than the same semicircular shape. .

By having the shape of the locking step 132, even when the rotating shaft 121 is inserted with a rough angle can be easily coupled to the connecting groove 131.

In addition, the locking step 132 may have a slope in the direction of the connection groove 131 in the insertion direction of the rotary shaft 121, as shown in Figure 7, by inserting the rotary shaft 121 by this structure It can serve as a guide to the appropriate location.

The non-return damper 150 is a component that is mounted to the tubular part 200 to open and close the air outlet 115 formed in the tubular part 200 according to the opening and closing of the blocking plate provided therein. Such a backflow prevention damper 150 may be provided in an outer shape corresponding to the inner shape of the tubular part 200 in order to be mounted to the tubular part 200 inside the housing 110. In detail, the non-return damper 150 may be provided in a conformal outer shape corresponding to the circular cross-sectional shape of the tubular part 200, that is, the circular cross-sectional shape.

Accordingly, the backflow prevention damper 150 may be fitted to the tubular portion 200 to be matched. That is, the backflow prevention damper 150 may be disassembled as well as coupled to the tubular portion 200 inside the housing 110. Here, the backflow prevention damper 150 may be provided with a length shorter than the entire length of the tubular portion 200 and inserted into the tubular portion 200. Therefore, when the non-return damper 150 is inserted into the tubular portion 200, the non-return damper 150 is unexposed to the outside.

Therefore, when a problem occurs in the backflow prevention damper 150 itself or when maintenance, such as cleaning thereof, is necessary, the user directly disassembles the backflow prevention damper 150 inside the housing 110 to easily perform the above-described operation. Unlike the existing method, it is possible to reduce the trouble of having to solve the problem by the expert, and it is convenient to use, and it can effectively reduce the time or cost required by the existing method.

In addition, the backflow prevention damper 150 may further include a handle 151 protruding toward an inner direction of the housing 110 as shown in FIGS. 2 to 5. Such a handle 151 may be provided in various forms that can be gripped by the user, but may be formed in a plate shape as shown in the present invention.

Accordingly, the user may grip the handle 151 protruding from the backflow prevention damper 150 to attach and detach the backflow prevention damper 150 to the tubular portion 200 inside the housing 110. At this time, one end portion in the longitudinal direction of the non-return damper 150 may be in contact with the step member 210 provided on the inner circumferential surface of the tubular portion 200 as shown in FIGS. 3 and 4. The stepped member 210 may be provided on the entire inner circumferential surface or a portion of the inner circumferential surface of the tubular portion 200 in a longitudinal direction portion of the tubular portion 200. In the embodiment of the present invention, as the tubular portion 210 is composed of two tubular members having different inner diameters, the stepped member 210 is formed on the point where the two tubular members are connected to each other. Although not limited thereto. The stepped member 210 as described above, the backflow prevention damper 150 is inserted through the longitudinal one side of the tubular portion 200 so that the backflow damper 150 is disposed in a predetermined position on the longitudinal direction of the tubular portion 200 ) Serves as a stopper defining the linear direction of movement. Therefore, as the user pushes the non-return damper 150 in the tubular portion 200 to the direction in which the stepped member 210 is disposed, one end of the longitudinal direction of the non-return damper 150 is the stepped member 210. When contacted with, the linear movement of the non-return damper 150 is limited and may be disposed on a predetermined mounting position.

Therefore, even if the non-return damper 150 is matched to the tubular portion 200 as described above, the user can easily detach the inside of the housing 110 by holding the handle 151, there is an advantage in use convenience. .

Meanwhile, as described above, the non-return damper 150 guides the coupling and disassembly direction in a detachable direction coupled to the tubular part 200, and the non-return damper in a state where one end of the longitudinal direction is in contact with the stepped member 210. A coupling groove 115a formed on a surface where the outer surface of the backflow prevention damper 150 and the inner surface of the tubular portion 200 are in contact with each other to define a coupling position of the 150; And a coupling protrusion 151a.

The coupling groove 115a may be provided on the outer surface of the backflow prevention damper 150 or the inner surface of the tubular portion 200. The coupling groove 115a may be formed in a groove shape recessed along the detachment direction of the backflow prevention damper 150, and may be provided in plurality in some cases. In the present invention, the coupling groove 115a may be formed on the inner side surface of the tubular portion 200. That is, when the coupling protrusion 151a to be described later is inserted into or separated from the coupling groove 115a, the coupling groove 115a guides the coupling protrusion 151a along the length direction, that is, the detachment direction of the backflow prevention damper 150. can do.

The coupling protrusion 151a may be provided on the outer surface of the backflow prevention damper 150 corresponding to the coupling groove 115a or the inner surface of the air outlet 115. The coupling protrusion 151a may be formed in the form of a protrusion that protrudes along the detachment direction of the backflow prevention damper 150, and may be provided in a number corresponding to the coupling groove 115a in some cases. In the present invention, the coupling protrusion 151a may be formed on the outer surface of the backflow prevention damper 150. That is, when the coupling protrusion 151a is inserted into or separated from the coupling groove 115a described above, the coupling protrusion 151a guides along the lengthwise direction of the coupling groove 115a, that is, the detachment direction of the backflow prevention damper 150. Can be.

Accordingly, when the non-return damper 150 is detached from the tubular part 200 inside the housing 110, the non-return damper 150 is coupled along the detachable direction by the coupling structure of the coupling groove 115a and the coupling protrusion 151a described above. And guided in the disassembly direction. In addition, when the backflow prevention damper 150 is coupled to the tubular portion 200 in the interior of the housing 110, rotation may be prevented by engaging with each other by a coupling structure of the coupling groove 115a and the coupling protrusion 151a. Can be.

Therefore, the non-return damper 150 may be easily coupled to the tubular part 200 within the housing 110 or may be easily disassembled from the tubular part 200, thereby providing a convenient convenience. In addition, when the backflow prevention damper 150 is coupled to the tubular portion 200, the backflow prevention damper 150 is always the same shape because the rotation is prevented by the coupling structure of the coupling groove 115a and the coupling protrusion 151a. Since the furnace tubular part 200 is opened and closed, the polluted air may be efficiently exhausted to the outside of the fan.

In addition, the damper-embedded fan 100 according to the present invention may further include a cover 190. The cover unit 190 may be formed in a plate shape having an area corresponding to the inlet 113 of the housing 110, and foreign matter introduced into the housing 110 together with the contaminated air is introduced into the building. In order to prevent the fall of the inlet 113 of the housing 110 is provided on the outside of the housing 110 in a state of blocking. In this case, the cover 190 is preferably disposed at a predetermined interval from the inlet 113 of the housing 110, which forms a space in which contaminated air can be introduced into the inlet 113 of the housing 110. For sake.

Here, the cover 190 may use a variety of detachable methods, such as a bolting method, a fastening method or a magnetic coupling method in order to be detachably mounted on the outside of the housing 110, in the present invention, the housing (using a magnetic coupling method) 110) It can be easily mounted on the outside. More specifically, the cover unit 190 may be magnetically coupled to the outside of the housing 110 by providing the magnet 170 at the connection portion of the outer portion of the cover unit 190 and the housing 110.

Accordingly, the cover 190 may be detachably mounted from the outside of the housing 110. That is, the cover 190 may be disassembled as well as mounted outside the housing 110.

Therefore, when a problem occurs in the cover 190 itself, or maintenance, such as cleaning thereof, the user can easily perform the above-described operation by disassembling the cover 190 directly from the outside of the housing 110. There is an advantage in using it.

For example, as described above, when the built-in damper fan 100 according to the present invention has a problem with each of the components provided in the housing 110 or needs cleaning thereof, the user directly performs the above-described operation. As described above, the detachment process of each component can be briefly described as follows.

First, the user may disassemble the cover 170 from the outside of the housing 110. In this case, since the cover 170 is detachably mounted to a part of the outer surface of the housing 110 through a magnetic coupling method, the cover 170 may be easily disassembled by the user.

Next, the user may disassemble the panel 160 inside the housing 110. In this case, since the panel 160 is detachably mounted to a portion of the inner surface of the housing 110 through a magnetic coupling method, the panel 160 may be easily disassembled by the user.

Next, the user may disassemble the impeller 130 inside the housing 110. At this time, since the impeller 130 is detachably mounted to the rotating shaft 121 of the motor 120 through a magnetic coupling method, the impeller 130 may be easily disassembled by the user.

Next, the user may disassemble the backflow prevention damper 150 inside the housing 110. At this time, the non-return damper 150 is detachably mounted to the tubular part 200 by being fitted in a fitting manner so that it can be disassembled by the user very easily.

As such, the user can sequentially disassemble the above-described components in the above order and take them out through the inlet 113 of the housing 110, so that each component in which the problem occurs can be directly repaired or replaced, and the cleaning thereof. Etc. Maintenance can be performed. On the contrary, the user may sequentially recombine the above components in reverse order.

As such, the damper built-in ventilator 100 according to the present invention can perform the above operation directly without passing through the expert, unlike the existing, the trouble to solve the problem through the expert, or to perform maintenance, such as cleaning This can reduce the time and cost required for this.

100: damper built-in fan 110: housing
111: air flow chamber 113: inlet
115: air outlet 115a: coupling groove
120: motor 121: rotating shaft
130: impeller 131: connecting groove
132: locking step 150: backflow prevention damper
151a: engaging projection 160: panel portion
170: magnet 190: cover

Claims (10)

A housing having an air flow chamber formed therein and having a tubular portion communicating with the air flow chamber;
An impeller provided in the air flow chamber formed in the housing and rotatably connected to a rotation shaft of the motor; And
And a backflow prevention damper for opening and closing an air outlet formed in the tubular part.
A stepped member is provided on the entire inner circumferential surface or a portion of the inner circumferential surface of the tubular part,
The backflow prevention damper,
It is inserted into the tubular portion from the inside of the housing and provided in a mating form corresponding to the inner form of the tubular portion, one end portion thereof in the longitudinal direction is in contact with the stepping member,
A coupling groove and a coupling protrusion formed on a surface where the outer surface of the backflow damper and the inner surface of the tubular portion are in contact with each other to define a coupling position of the backflow damper in a state in which one end of the longitudinal direction is in contact with the stepped member; and,
The non-return damper further includes a blocking plate which is rotated in the direction in which the air outlet is disposed by the polluted air, and a handle which protrudes toward the inner direction of the housing from a central portion of the blocking plate, wherein the tubular portion A damper-embedded fan, which is inserted into the tubular portion and is not exposed to the outside while having a length shorter than the entire length.
delete delete The method of claim 1,
The impeller,
Sirocco fan is provided in the form of a cylindrical fan and blows air in the tangential direction during rotation.
The air outlet,
A damper-embedded fan, characterized in that the tubular shape extending from the rectangular cross-sectional shape to a circular cross-sectional shape so that the air sent by the impeller is smoothly discharged.
The method of claim 4, wherein
The backflow prevention damper,
And a damper-embedded ventilator having a conformal outer shape corresponding to a circular cross-sectional shape of the air outlet and fitted into a circular cross-sectional shape.
The method of claim 1,
And a impeller detachment means for detachably coupling the impeller and the motor rotation shaft.
The method of claim 6, wherein the impeller detachment means,
And a magnet provided at a connection portion between the impeller and the motor rotation shaft.
The method of claim 1,
As an impeller detachable means for detachably coupling the impeller and the motor shaft,
The motor rotation shaft is formed of a magnetic material that is magnetically coupled to the magnet is formed of a shaft structure chamfered at least a portion,
The impeller is provided with a connecting groove into which the rotating shaft can be inserted at the rotation center and a magnet provided inside the connecting groove,
The connecting groove has a locking jaw for the rotation direction of the rotary shaft in a state in which the rotating shaft is chamfered, the locking jaw is formed to form a play with respect to the rotation direction of the rotating shaft inserted into the connecting groove A damper built-in fan, characterized in that the.
The method of claim 8,
The axis of rotation is in the form of a cross-section perpendicular to the axial direction has the form of a circle chamfered part of the arc,
A shape of a cross section of at least a portion of the connecting groove corresponding to the rotating shaft having a circular cross section in which a portion of the arc is chamfered occupies only a part of the chamfered area by the cross section of the locking jaw and surrounds an outer portion of the rotating shaft. A damper built-in fan, characterized by having a close shape.
The method according to claim 8 or 9,
The catching jaw is characterized in that the slope formed to guide the insertion of the rotary shaft from the insertion direction of the rotary shaft in the direction of the connecting groove, damper built-in fan.

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