KR20180068650A - blowing apparatus and air cleaner with blowing apparatus - Google Patents

Abstract

A blowing apparatus and an air cleaner with the blowing apparatus according to an embodiment of the present invention comprise: a fan; a fan housing accommodating the fan; and an air guide apparatus arranged at the top of the fan to guide the air upwardly, wherein a guide vane for upwardly guiding the air passed through the fan is provided in the air guide apparatus, and a chord length of the guide vane is formed to have a 5-26% value of the outer diameter (d) of the air guide apparatus such that the chord length of the guide vane is optimized to convert a flow direction of the air. Therefore, the flow direction of the air can be easily converted to a shaft direction. According to the present invention, a rotation composition of a flow speed is reduced such that noise can be reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air cleaner having an air blowing device and an air blower,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air purifier including a blowing device and a blowing device, and more particularly, to an air blowing device for reducing noise and vibration by reducing the flow resistance of air and an air purifier equipped with the blowing device.

The air purifier is understood to be an apparatus for sucking contaminated air to purify it, and then discharging the purified air. For example, the air cleaner may include a blowing device for introducing outside air into the interior of the air cleaner, and a filter capable of filtering dust and germs in the air. Generally, an air purifier is configured to purify an interior space such as a home or office.

The inside of the air cleaner is provided with a blowing device for sucking and filtering the air and discharging the filtered air again. The fan unit includes a blowing fan and a fan housing for receiving the blowing fan. The fan housing has an inlet for suctioning air and a discharge outlet for discharging the air.

The blowing fan of the blower may be provided as a centrifugal fan. The centrifugal fan is a fan which sucks air in the axial direction and discharges it in the radial direction. Generally, a blower equipped with a centrifugal fan includes a bell mouth installed on a suction side of a centrifugal fan for guiding the flow of sucked air, a rotating plate having a hub for receiving a motor and a blade coupling portion, A plurality of blades, and a shroud connected to the plurality of blades to guide the flow of air.

On the other hand, the air blowing device includes a guide device for guiding a direction of flow of air sucked out from the blowing fan to be discharged to the outside. The guide device is provided with a guide vane, and the flow direction of the air can be changed by the shape and angle of the guide vane.

The following is a list of prior literature information.

1. Public number: 10-2014-0005145 (public date: January 14, 2014)

Title: Radial diffuser vane for centrifugal compressors

In the above prior art, the diffuser vanes having an S-shaped camber line having a constant function are used to reduce the load on the leading and trailing edges of the vane, gradually increase the load toward the middle of the vane, Can be obtained.

However, the above-mentioned prior art only shows the influence of the air resistance (load) on the sectional shape of the vane.

An object of the present invention is to provide an air purifier equipped with a blowing device and a blowing device capable of solving the noise problem caused by the number of vanes for guiding the flow direction of the air discharged from the air blowing device.

Another object of the present invention is to provide an air purifier equipped with a blowing device and a blowing device capable of solving the problem of increasing the vibration of the blowing device due to the switching of the air flow direction.

It is still another object of the present invention to provide an air cleaner having an air blowing device and a blowing device capable of solving the problem of increased power consumption due to air flow interference in the air blowing device.

It is still another object of the present invention to provide an air purifier having an air blowing device and a blowing device capable of solving the problem of loss generated when the air passing through the centrifugal fan is changed in the direction of flow in the axial direction, .

It is still another object of the present invention to provide an air cleaner having an air blower and a blower capable of solving the problem that the flow rate of air finally discharged in the axial direction is reduced in a blower having a centrifugal fan.

The air cleaner provided with the air blowing device and the air blowing device according to the embodiment of the present invention includes a fan housing for accommodating the fan and the fan, and an air guide device disposed on the upper side of the fan to guide the air upward, The apparatus is provided with a guide vane for guiding upwardly the air passing through the fan and the length of the chord of the guide vane is formed to have a value of 5% to 26% of the outer diameter (d) of the air guide apparatus A code length of the guide vane optimized for switching the air flow direction is provided. Therefore, the flow direction of the air can be easily switched in the axial direction. According to this, the rotational component of the flow velocity can be reduced to reduce the noise.

In the air cleaner equipped with the blowing device and the blower according to the embodiment of the present invention, the number Y of guide vanes is expressed by the formula Y = 183.19 L (-0.592) with respect to the cord length L of the guide vane So that it is possible to reduce the vibration of the air blowing device because it provides the optimum number of switching the flow of the air passing through the fan in the axial direction.

The air purifier provided with the air blowing device and the air blowing device according to the embodiment of the present invention includes a leading edge forming a side end portion into which air flows, a trailing edge forming a side end portion through which air is discharged, And a guide vane protruding from the leading edge toward the trailing edge and having a protrusion extending from the leading edge toward the trailing edge. The cord length of the guide vane is determined to be an optimal length by the outer diameter of the air guide device, Since the number of the guide vanes is optimally selected by Equation 1, it is possible to reduce the phenomenon that the rotational flow of the remaining air that can not be switched in the axial direction interferes with the air flowing in the axial direction. Therefore, the driving power of the centrifugal fan for generating the same air volume can be reduced. And the power consumption of the blower can be reduced.

The air cleaner provided with the air blowing device and the air blowing device according to the embodiment of the present invention includes a centrifugal fan and a fan housing for accommodating the centrifugal fan. The air cleaner rotates upward through the blades of the centrif atal fan, And the guide vane is provided in the form of an airfoil so that the axial directional change of the air passing through the centrifugal fan is optimized so that the loss in the air flow direction can be reduced.

The air cleaner provided with the air blowing device and the air blowing device according to the embodiment of the present invention is provided with the guide vane capable of maximizing the ratio of the rotation direction component of the air passing through the fan and the fan to the axial direction component, The flow rate of the finally discharged air can be relatively increased.

According to the present invention, the quietness of the air cleaner provided with the air blowing device and the air blowing device is improved due to the noise reduction.

According to the present invention, the air radiated in the radial direction by the rotation of the centrifugal fan provided in the air blower is optimized to change the direction of flow in the axial direction, so that the vibration generated when passing through the vane is relatively reduced. Therefore, as the vibration of the air cleaner equipped with the air blowing device and the air blowing device is reduced, the stability and reliability are improved.

According to the present invention, since the driving power of the centrifugal fan for generating the same air volume can be reduced, the power consumption can be reduced. Therefore, the burden of the user's electric power cost is reduced and the economical efficiency is improved.

According to the present invention, since the loss due to the switching of the air flow direction can be reduced, the efficiency with respect to the discharge amount of the air discharged in the axial direction of the air blowing device to the suction amount of the air sucked into the air blowing device The energy efficiency can be improved.

According to the present invention, it is possible to more easily change the air in the axial direction from the air blowing device, and thus the air volume of the air blowing device can be relatively increased.

According to the present invention, since the number of vanes is optimized according to the length of the vane, which minimizes the loss due to the flow of air, the vane having the centrifugal fan has advantages such as standardization of the vane and improvement of productivity.

According to the present invention, since a cylindrical filter member is provided to suck and filter air in all directions, the cleaning ability of the air cleaner can be improved.

1 is a front view showing an appearance of an air cleaner equipped with a blower according to an embodiment of the present invention;
2 is a cross-sectional view showing the internal structure of an air cleaner equipped with a blower according to an embodiment of the present invention;
FIG. 3 is an exploded view showing a part of an air purifier provided with a blower according to an embodiment of the present invention.
4 is an enlarged view showing a part of the structure of the blower according to the embodiment of the present invention.
5 is a cross-sectional view showing an air flow of a blower according to an embodiment of the present invention
6 is a graph showing experimental data showing a stream line of air passing through a conventional air blowing device and an air blowing device according to an embodiment of the present invention.
7 is a plan view of a blower according to an embodiment of the present invention.
8 is an enlarged view showing a vane of a blower according to an embodiment of the present invention;
9 is a cross-sectional view taken along line I-I '
10 and 11 are graphs showing experimental results comparing the noise levels of the conventional ventilator and the ventilator according to the embodiment of the present invention

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

FIG. 1 is a front view showing an appearance of an air cleaner provided with a blower according to an embodiment of the present invention, FIG. 2 is a sectional view showing the internal structure of an air cleaner equipped with a blower according to an embodiment of the present invention, 3 is an exploded view showing a part of an air purifier provided with a blower according to an embodiment of the present invention.

1 to 3, the air purifier 10 according to the embodiment of the present invention may generate an air flow. In this case, the air flow may form a flow for sucking the indoor air present on the lower side of the air cleaner 10.

The air cleaner 10 includes a case 101 forming an outer appearance.

The case 101 may have a cylindrical shape. The upper portion of the case 101 may be configured to have a smaller diameter than the lower portion. That is, the case 101 may have a truncated conical shape.

On the other hand, the air purifier 10 may be called an air purifying module in that it functions as a filter to purify the air.

The case 101 may include a separating unit (not shown) in which two parts constituting the case 101 are joined or separated. The case 101 may further include a hinge portion (not shown) provided on the opposite side of the separating portion. The two parts can relatively rotate about the hinge part. Accordingly, when at least one of the two parts rotates, the case 101 is opened and can be separated from the air cleaner 10. [ In addition, the case 101 can be opened to replace or repair internal components of the air blowing apparatus 100.

In the case 101, a suction portion 102 through which air is sucked is formed. The suction unit 102 includes a through hole formed through at least a portion of the case 101. A plurality of the suction units 102 are formed.

The plurality of suction portions 102 are uniformly formed in the circumferential direction along the outer peripheral surface of the case 101 so that air can be sucked in any direction with respect to the case 101. That is, air can be sucked in the direction of 360 degrees with reference to the vertical center line passing through the inner center of the case 101.

As described above, the case 101 is formed in a cylindrical shape, and a plurality of the suction portions 102 are formed along the outer peripheral surface of the case 101, so that the suction amount of air can be increased. In addition, as in the case of the conventional air cleaner, the effect of avoiding the hexahedron shape having the corner portion can reduce the flow resistance to the air to be sucked.

The air sucked through the suction unit 102 can flow in a substantially radial direction from the outer circumferential surface of the case 101.

Define the direction. 1, the vertical direction is referred to as an axial direction, and the horizontal direction is referred to as a radial direction. The axial direction may correspond to the center axis direction of the fan 160, which will be described later, that is, the motor axial direction of the fan. The radial direction can be understood as a direction perpendicular to the axial direction. The circumferential direction is understood to be an imaginary circular direction formed when the radial distance is rotated around the axial direction as a turning radius.

The air cleaner (10) further includes a base (20) provided below the case (101) and placed on the ground.

The base (20) is spaced downward from the lower end of the case (101). A base suction part 103 is formed in a space between the case 101 and the base 20.

The air sucked through the base suction unit 103 can be flowed upward through the suction port 112 of the suction grill 110 provided at the upper side of the base 20.

That is, the air cleaner (10) includes a plurality of suction units (102, 103). The air present in the lower portion of the indoor space can be easily introduced into the air cleaner 10 through the plurality of suction units 102 and 103. Therefore, the intake amount of air can be increased.

A discharge unit 105 is formed on the air cleaner 10. The discharge unit 105 may be formed in a discharge grill of a discharge guide device 190 provided in the air cleaner 10. The discharge guide device 190 forms an upper end outer surface of the air cleaner 10. The air discharged through the discharge portion 105 flows upward in the axial direction.

The air cleaner 10 further includes a suction grill 110 disposed on the upper side of the base 20.

The base 20 includes a base body 21 placed on the ground and a base protrusion 22 protruded upward from the base body 21 and on which the suction grill 110 is placed.

By the base projection 22, the base body 21 and the suction grill 110 are spaced from each other. Between the base 20 and the suction grill 110, a base suction part 103 for forming an air suction space is included.

The suction grill 110 includes a substantially ring-shaped grill body 111 and an inlet 112 formed at an edge of the grill body 111. The suction ports 112 may be spaced apart from one another along the rim. The plurality of suction ports 112 may communicate with the base suction unit 103.

The air cleaner 10 further includes a filter member 120 disposed above the suction grill 110 and filtering air.

The air sucked through the suction port 112 and the base suction unit 103 can pass through the pulter member 120. That is, the air can flow through the outer peripheral surface of the cylindrical filter member 120 into the interior thereof. That is, the filter member 120 may have a cylindrical shape and a filter surface for filtering air.

The suction grill 110 includes a lever support portion 113 which forms an upper surface of the grill body 111 and supports the lever device 142 and a lever support portion 113 which is recessed in the inner radial direction from the outer peripheral surface of the grill body 111 The groove portion 114 is further included. The groove 114 may provide a space through which the handle 144 can move.

The air cleaner (10) is provided with a lever device (142) provided on the suction grill (110) and operable by a user.

The lever device 142 includes a lever body 143 having a substantially ring shape and being rotatably provided.

The lever body 143 includes a lever protrusion 145 provided at an edge of the lever body 143. The lever protrusion 145 protrudes upward from the upper surface of the rim of the lever body 143 and may be spaced apart from each other. The plurality of lever projections 145 is understood as a configuration having an inclined surface in order to move the support device 140 to be described later, either upward or downward.

On the outer peripheral surface of the lever body 143, a handle 144 is provided. The user can grasp the handle 144 and rotate the lever body 143 clockwise or counterclockwise.

The air cleaner 10 further includes a supporting device 140 for supporting the filter member 120 on the lever device 142. The lever device 142 supports the lower surface of the support device 140. The support device 140 may include a support protrusion (not shown) that contacts the lever protrusion 145. The support protrusions may protrude downward from the lower surface of the support device 140 and may include a plurality of protrusions corresponding to the lever protrusions 145. In addition, the support projection includes an inclined surface.

The lever protrusion 145 may be rotated together with the lever body 143 during the rotation of the lever body 143. [ At this time, when the upper portion of the lever projection 145 comes into contact with the lower portion of the support protrusion, the lever body 143 pushes the support device 140 upward. When the supporting device 140 moves upward, the filter member 120 is in a state of being coupled to the air cleaner 10.

On the other hand, when the lower portion of the lever projection 145 abuts the upper portion of the support protrusion, the support device 140 descends downward. When the supporting device 140 descends downward, the filter member 120 is in a detachable state (released state) from the air cleaner 10.

The air cleaner (10) further includes a filter frame (130) forming a space for mounting the filter member (120). In detail, the filter frame 130 includes a first frame 131 forming a lower portion of the filter frame 130 and a second frame 132 forming an upper portion of the filter frame 130.

The first frame 131 has a substantially ring-shaped portion. The ring-shaped inner space of the first frame 131 forms at least a part of the air passage passing through the filter frame 130.

The lever device 142 and the support device 140 may be positioned on the inner circumferential surface of the first frame 131. The upper surface of the support device 140 includes a seating surface on which the filter member 120 is placed. A handle space portion 131a for allowing the handle 144 of the lever device 142 to be operated is defined in the cut-away space of the first frame 131. The handle 144 is located in the handle space 131a and can be operated clockwise or counterclockwise.

The second frame 132 is spaced upward from the first frame 131. The second frame 132 has a substantially ring shape. The ring-shaped inner space of the second frame 132 forms at least a part of an air flow path passing through the filter frame 130. The upper portion of the second frame 132 may support the fan housing 150, which will be described later.

The filter frame 130 further includes a filter support 135 extending upward from the first frame 131 toward the second frame 132. The first and second frames 131 and 132 may be separated from each other by the filter support 135. A plurality of filter supports 135 may be provided and the filter supports 135 may be arranged in the circumferential direction and connected to the rim of the first and second frames 131 and 132.

The mounting space of the filter member 120 is defined by the first and second frames 131 and 132 and the plurality of filter supports 135.

In the mounting space, the filter member 120 can be detachably mounted. The filter member 120 has a cylindrical shape, and air can be introduced through the outer circumferential surface of the filter member 120. In the process of passing through the filter member 120, impurities such as fine dust in the air can be filtered.

Since the filter member 120 has a cylindrical shape, it is possible to introduce air in any direction with respect to the filter member 120. Therefore, the filtering area of the air can be increased.

The mounting space may be formed in a cylindrical shape corresponding to the shape of the filter member 120. The filter member 120 may be slidably received in the mounting space during the mounting process. On the contrary, the filter member 120 can be slidably drawn out from the mounting space in the separating process.

In other words, when the handle 144 is operated with the filter member 120 placed on the upper surface of the supporting device 140, the filter member 120 moves downward and is in the unlocked position. Then, the filter member 120 is slid radially outward, and can be separated from the mounting space.

On the other hand, when the filter member 120 is separated from the mounting space, the filter member 120 is slid radially inward toward the mounting space and supported on the upper surface of the supporting device 140, As shown in Fig. At this time, the filter member 120 is in the engagement position.

On the other hand, a support cover 136 may be coupled to the outside of the filter support 135.

The air cleaner 10 is provided with a flow pressure of air to suck air into the suction ports 102 and 103 and is disposed above the filter member 120 to filter the filtered air passing through the filter member 120 And further includes an air blowing device 100 that flows upward.

The fan unit 100 includes a fan housing 150 installed at an outlet side of the filter member 120. In the fan housing 150, a fan 160 is accommodated. The fan housing 150 may be supported by the filter frame 130.

A fan inlet 152 for guiding the inflow of air into the fan housing 150 is included in the lower portion of the fan housing 150. The fan inlet 152 may be provided with a grill to prevent a user from inserting a finger or the like into the fan housing 150 when the filter member 120 is detached.

FIG. 4 is an enlarged view showing a part of the structure of a blower according to an embodiment of the present invention, and FIG. 5 is a cross-sectional view showing an air flow of a blower according to an embodiment of the present invention.

Referring to FIGS. 3 and 4, the fan apparatus 100 further includes a fan 160 that provides a flow pressure of air through rotation.

The fan 160 is placed above the fan inlet 152. The fan 160 includes a centrifugal fan for introducing air in the axial direction and discharging air upward in the radial direction.

The fan 160 includes a hub 161 to which a rotary shaft of a fan motor 165 as a centrifugal fan motor is coupled and a shroud 162 and a hub 161 spaced apart from the hub 161. [ And a plurality of blades 163 disposed between the shrouds 162. The fan motor 165 may be coupled to the fan 160.

The hub 161 may have a bowl shape whose diameter decreases toward the downward direction. The hub 161 includes a shaft coupling portion to which the rotation shaft is coupled and a first blade coupling portion that extends upward from the shaft coupling portion and extends obliquely.

The shroud 162 includes a lower end portion formed with a shroud suction port through which the air having passed through the fan inlet portion 152 is drawn, and a second blade coupling portion extending upward from the lower end portion.

One side of the blade 163 is coupled to the first blade coupling portion of the hub 161 and the other side is coupled to the second blade coupling portion of the shroud 162. The plurality of blades 163 may be spaced apart from each other in the circumferential direction of the hub 161.

The air passing through the filter member 120 flows upward into the fan housing 150 through the fan inlet 152. The air flows in the axial direction of the fan 160 and flows out through the blade 163.

At this time, the edge of the blade may be inclined outwardly upward with respect to the axial direction, corresponding to the flow direction of the air, so that the outflowing air can flow upward in the radial direction.

The air blowing device 100 further includes an air guide device 170 coupled to the fan 160 to guide the flow of air passing through the fan 160.

The air guide device 170 is positioned above the fan housing 150. For example, the air guide device 170 may be stacked to have the same outer diameter as the fan housing 150 to guide the flow of air passing through the fan 160.

The air guide device 170 includes an outer wall 171 having a cylindrical shape and an inner wall 172 having a cylindrical shape located inside the outer wall 171. The outer wall 171 is disposed so as to surround the inner wall 172. Between the inner circumferential surface of the outer wall 171 and the outer circumferential surface of the inner wall 172, a first air flow path 172a through which air flows is formed. That is, the diameter of the outer wall 171 is larger than the diameter of the inner wall 172.

The diameter of the outer wall 171 can be understood as the outer diameter of the air guide device 170 and the diameter of the inner wall 172 can be understood as the inner diameter of the air guide device 170.

The air guide device 170 further includes a motor receiving portion 173 extending downward from the inner wall 172 to receive the fan motor 165. The motor receiving portion 173 may have a bowl shape whose diameter decreases toward the lower portion. A motor coupling part is provided on one side of the fan motor 165, and the motor coupling part guides the fan motor 165 to be fixed to the air guide device 170.

The shape of the motor receiving portion 173 may correspond to the shape of the hub 161. [ The motor receiving portion 173 may be inserted into the hub 161.

The fan motor 165 may be supported on the motor housing 173. The rotation shaft of the fan motor 165 extends downward from the fan motor 165 and may be coupled to the shaft coupling portion of the hub 161 through the bottom portion of the motor receiving portion 173. [

The air guide device 170 further includes a guide vane 175 disposed in the first air passage 172a.

The guide vane 175 extends from the outer circumferential surface of the inner wall 172 to the inner circumferential surface of the outer wall 171. The guide vanes 175 may be spaced apart from one another.

The plurality of guide vanes 175 guide the air introduced into the first air passage 172a of the air guide device 170 through the fan 160 upward.

The guide vane 175 may extend obliquely upward from a lower portion of the outer wall 171 and the inner wall 172. For example, the guide vane 175 may be rounded to guide the air to flow upwardly. A detailed description thereof will be described later.

The air blowing device 100 further includes a discharge guide device 190 having a discharge part 105 for discharging the air passing through the air guide device 170 to the outside. For example, the discharge guide device 190 may include a grill.

The flow of air sucked and discharged into the air blowing apparatus 100 will be described in detail with reference to FIG.

The air that has passed through the filter member 120 flows upward due to the flow pressure generated through the rotation of the fan 160. The upwardly flowing air flows into the fan housing 150 through the fan inlet 152. The air flowing into the fan housing 150 flows in the axial direction of the fan 160 and flows through the shroud inlet formed at the lower end of the shroud 162. The air introduced into the shroud intake port flows upward in the radial direction via the blade 163 along the inclination of the blade 163. The outflowed air flows into the first air passage 172a of the guide device 170 positioned above the fan housing 150. [

As described above, a plurality of guide vanes 175 are fixedly positioned in the first air passage 172a. The plurality of guide vanes 175 guide the air flowing in the first air passage 172a in the axial direction, that is, upward.

On the other hand, most of the air discharged to the upper side of the radial direction through the blade 163 is composed of a fluid component in the circumferential direction and a fluid component in the radial direction.

Hereinafter, the air discharged through the blade 163 is referred to as fan discharge air for the sake of detailed explanation.

The fan discharge air is mainly composed of a radial velocity component and a circumferential velocity component due to the rotation of the blade 163. Accordingly, the fan discharge air flows upward through the blade 163, forming a swirl flow that rotates along the rotation of the blade 163.

The upwardly rotating flow through the blades 163 is diverted to axial flow by a plurality of guide vanes 175 provided in the axial direction.

That is, the velocity component of the fan discharge air flowing through the guide vane 175 decreases in the radial direction and the circumferential direction component, and the axial component becomes relatively large. Therefore, the decreasing rate of the radial and circumferential velocity components and the increasing rate of the axial velocity components are determined according to the axial length of the guide vane 175. In other words, the ratio of guiding the radial and circumferential flow in the axial direction varies depending on the axial length (cord length to be described later) of the guide vane 175.

The fan discharge air passing through the centrifugal fan includes a first air passage 172a formed in the space between the circular outer wall 171 and the circular inner wall 172 having a smaller diameter than the outer wall 171, . A plurality of guide vanes 175 are disposed at a predetermined distance from the first air passage 172a. Therefore, interference in the spacing spaces between the plurality of guide vanes 175 as well as the axial length of the single guide vane 175 also affects the axial direction of the flow direction of the fan discharge air.

That is, in order for the flow of the fan discharge air to be more easily changed in the axial direction, the number of guide vanes 175 should be determined according to the area and volume formed by the first air passage 172a.

The air passing through the fan 160 is radially and circumferentially spaced from the guide vane 175 in accordance with the axial length of the guide vane 175 (chord length to be described later) It is possible to reduce the velocity component at an optimal ratio and to increase the velocity component in the axial direction at an optimum ratio. That is, if the number of the appropriate guide vanes 175 and the axial length of the guide vane 175 are determined, the flow direction of the fan discharge air can be maximally changed in the axial direction.

If the flow direction of the fan discharge air can be changed as much as possible in the axial direction, the air that has passed through the guide vane 175 is reduced in the component that generates rotation in the velocity component, Radial and circumferential velocity components) can be reduced, and the air discharged in the axial direction has a relatively larger discharge amount.

6 is experimental data showing a stream line of air passing through a conventional ventilator and the ventilator according to an embodiment of the present invention.

6, the influence of the number of the guide vanes 175 and the axial direction length of the guide vane 175 on the flow direction of the fan discharge air and the flow direction of the air passing through the guide vane 175 Can be confirmed.

6 can not be installed within the range of the axial length of the guide vane 175 to be described later and the number of the guide vanes 175, the air discharged from the air blowing apparatus 100 is finally rotated The direction component (radial direction and circumferential velocity component) is not sufficiently converted into the axial component, so that the flow of the air that has passed through the guide vane 175 rises with the swirl flow, As shown in Fig. This causes noise and vibration of the air blowing device 100.

6, when the air sucked into the fan 160 is finally discharged through the discharge guide 190, the ratio of the axial discharge flow air to the suction air of the fan 160 is relatively low Which means that the axial flow air is lost by the rotating flow air.

6, the rotational direction component (radial direction and circumferential velocity component) is set to be within the range of the axial length of the guide vane 175 to be described later and the range of the optimal number of the guide vanes 175 The axial component is sufficiently converted so that the air that has passed through the guide vane 175 flows mostly in the axial direction and the resistance to the axial flow is reduced and the flow amount of the air flowing in the axial direction is increased .

According to this, the ratio of the flowing air in the axial direction to the air sucked into the fan 160 is improved, which results in an improvement in efficiency. In addition, the resistance to axial air flow can be reduced to reduce the vibration and noise of the fan 100.

FIG. 7 is a plan view of a blower according to an embodiment of the present invention, FIG. 8 is an enlarged view showing a vane of a blower according to an embodiment of the present invention, and FIG. 9 is a sectional view taken along line I-I 'of FIG.

Referring to FIGS. 7 to 8, the guide vane 175 includes a rib body 175a extending upward in a round manner. The rib main body 175a includes a static pressure surface 175b forming a surface in which air flows and a negative pressure surface 175c forming an opposite surface of the static pressure surface 175b. The positive pressure surface 175b is concave and the negative pressure surface 175c is convex.

The rib main body 175a includes a leading edge 175d forming a side end portion into which air flows and a trailing edge 175e forming a side end portion through which air is discharged.

The leading edge 175d is formed to be rounded from the static pressure surface 175b toward the negative pressure surface 175c. With this configuration, some of the air introduced through the leading edge 175d can be guided by the static pressure surface 175b, and the remaining air can be guided by the negative pressure surface 175c. The air flowing to the negative pressure surface 175c passes through the plurality of protrusions 175f.

The plurality of protrusions 175f protrude from the negative pressure surface 175c and extend from the leading edge 175d toward the trailing edge 175e. The protrusion 175f has an airfoil shape in which the height protruding from the leading edge 175d toward the trailing edge 175e is reduced. Likewise, the guide vanes 175 also have an airfoil cross-section. That is, the longitudinal section I-I 'of the guide vane 175 has an airfoil shape.

The plurality of protrusions 175f are formed on the negative pressure surface 175c to prevent vortices from being generated on the negative pressure surface 175c and the air can easily flow upward.

On the other hand, the trailing edge 175e may have a saw-tooth shape in which the crests and valleys are repeated in the radial direction. With this configuration, there is a time difference in the air flowing out from the trailing edge 175e, that is, air from the mountain and the valley, and noise generation is reduced.

Meanwhile, the axial length L of the guide vane 175 may be referred to as a chord length of the guide vane 175.

The chord length L is defined as a straight line L connecting the leading edge (leading edge) 175d and the trailing edge (trailing edge) 175e in the cross section of the airfoil shape of the guide vane 175 . More specifically, the code length L is defined as a distance between a virtual first straight line passing through the leading edge 175d and a virtual second straight line passing through the trailing edge 175e parallel to the first straight line .

On the other hand, the cord length L is determined by the outer diameter d of the air guide device 170. Generally, as the outer diameter of the air guide device 170 increases, the volume of the first air passage 172a increases. When the volume of the first air passage 172a is increased, the cord length of the guide vane 175 for guiding the flow of air passing through the first air passage 172a in the axial direction is proportionally increased. Therefore, it can be understood that the cord length L of the guide vane 175, which guides the air passing through the fan 160 in the axial direction, is determined by the diameter of the air guide device 170 have.

The cord length L may be set to a value between 5% and 26% of the outer diameter d of the air guide device 170. [ More preferably, the guide vane 175 may have a cord length L of 9% to 26% of the outer diameter d of the air guide device 170. According to this, the air passing through the fan 160 can have an optimum ratio in which the rotational direction component is converted into the axial direction component when passing through the guide vane 175.

In other words, the cord length L may be formed to have a value between 5% and 26% of the diameter d of the air guide device 170. That is, the cord length L is determined to be 5% to 26% of the diameter d of the outer wall 171.

Meanwhile, the ratio of the air guided in the axial direction differs according to the ratio of the cord length L, whereby the ratio of the air guided in the axial direction among the plurality of guide vanes differs. Therefore, the total number of guide vanes 175 installed can also be determined by the code length L. [

That is, the total number of the guide vanes 175 can be determined according to the axial length of the guide vane 175, that is, the cord length L. [ As described above, the cord length L can be determined according to the diameter of the outer wall 171.

The number of the guide vanes 175 is relatively small when the cord length L is longer in the set range from the diameter d of the constant air guide device 170, More. This is because the longer the cord length L is, the longer the length of the guide of the air flow in the axial direction becomes, the higher the conversion ratio in which the rotational direction component of the flow velocity is converted into the axial component becomes higher.

If the total number of the guide vanes 175 is Y and the cord length is L, the relationship between the total number Y of the guide vanes 175 and the cord length L is defined as follows.

The total number of guide vanes Y = 183.19 × L ^ (- 0.592) (1)

However, in Equation (1), the cord length L is equal to or greater than 8 mm (L? 8 mm), and the unit is mm. And the number of guide vanes can be allowed up to ± 3 in the natural number of Y calculated.

For example, when the outer diameter d of the air guide device 170 is 300 mm, the cord length L may be between 15 mm and 78 mm. As described above, the cord length L can more preferably be set to a value between 27 mm and 78 mm.

When the cord length L is set to a maximum value of 78 mm, the total number Y of the guide vanes 175 is 13 according to the equation 1, and when the cord guide 170 has an outer diameter of 300 mm, Means the minimum number of vanes 175.

When the cord length L is set to a minimum value of 15 mm, the total number Y of the guide vanes 175 is 36 according to the equation 1, and when the cord guide 170 has an outer diameter of 300 mm, Which means the maximum number of vanes 175. In the case where a more preferable cord length ratio is applied (L = 27 mm), the total number Y of the guide vanes 175 is 26 according to Equation 1. This is because when the outer diameter of the air guide device 170 is 300 mm, Vane < / RTI >

FIGS. 10 and 11 are graphs for comparing noise levels of a conventional ventilator and a ventilator according to an embodiment of the present invention.

Hereinafter, when the outer diameter of the air cleaner 10, that is, the outer diameter d of the air guide device 170 is 300 mm, the preferable maximum number (26 pieces) of the guide vanes 175 The case where the minimum number (13) is satisfied and the case where the formula 1 is not satisfied are described in detail.

10 is a sectional view of the guide vane 175 when the outer diameter d of the air guide device 170 is 300 mm and the cord length L is 27 mm which is a 9% value of the outer diameter d. (DB) relative to the air volume (CMM) according to the number (26) of the guide vanes (175) and the number of guide vanes (175) outside the range of the equation (1).

Referring to FIG. 10, when the number (26) of the guide vanes 175 satisfying Equation 1 is set, it is confirmed that the noise is smaller than the case (13) .

11 is a sectional view of the guide vane 175 in the range of the above-mentioned formula 1 when the outer diameter d of the air guide device 170 is 300 mm and the cord length L is 78 mm which is 26% (DB) relative to the air volume (CMM) according to the number (13) of guide vanes (175) and the number of guide vanes (175) outside the range of the equation (1).

Referring to FIG. 11, when the number (13) of the guide vanes 175 satisfying Equation (1) is set, it is confirmed that the noise is less than the case (26) .

The guide vane 175 is bent by the number of the guide vanes 175 satisfying the condition of the formula 1 at a cord length L within a preferable range according to the outer diameter d of the air guide device 170, Is installed between the outer wall 171 and the inner wall 172, the noise and vibration can be reduced as compared with the case where the condition of Equation (1) is not satisfied.

According to this, compared with the number of guide vanes of the conventional ventilator which does not satisfy the expression (1), the power consumption for generating the same air volume is reduced. In another aspect, the fan apparatus 100 according to the embodiment of the present invention has an advantage that it can provide an improved air flow rate when the same power is consumed.

10: air cleaner 100: blower
160: fan 170: air guide device
190: Discharge guide device

Claims (11)

A fan housing accommodated in the fan housing to provide a flow pressure of air; and an air guide device coupled to the upper side of the fan to guide the flow of the air passing through the fan,
In the air guide apparatus,
outer wall;
An inner wall positioned inside the outer wall; And
And a plurality of guide vanes extending from the outer circumferential surface of the inner wall to the inner circumferential surface of the outer wall,
Wherein an axial length (L) of the guide vane is 5% to 26% of an outer diameter (d) of the air guide device. The method according to claim 1,
The number of guide vanes (Y)
Is a natural number satisfying the formula: Y = 183.19 x L (- 0.592). 3. The method of claim 2,
In the guide vane,
A leading edge forming a side end portion into which air flows;
A trailing edge defining a side end through which air is discharged; And
And a protrusion protruding from one side of the guide vane and extending from the leading edge toward the trailing edge. The method of claim 3,
Wherein the protrusion has an airfoil shape. The method according to claim 1,
The fan includes a centrifugal fan,
Wherein the outer wall and the inner wall have a cylindrical shape. A case having a suction portion;
A filter member for filtering the air sucked through the suction unit; And
And an air blowing device disposed above the filter member to flow the air passing through the filter member upward,
In the air blowing device,
A fan housing installed at an outlet side of the filter member;
A fan received in the fan housing; And
And an air guide device having an airfoil-shaped guide vane for guiding upwardly the air passing through the fan,
Wherein a chord length (L) of the guide vane is 5% to 26% of an outer diameter (d) of the air guide device. The method according to claim 6,
Wherein the air guide device is provided with an air passage through which the air passing through the fan flows, a plurality of the guide vanes being arranged in the air passage,
Wherein the number (Y) of guide vanes is a natural number satisfying Y = 183.19 x L (- 0.592). 8. The method of claim 7,
Wherein the filter member has a cylindrical shape. 9. The method of claim 8,
Further comprising a discharge guide device disposed above the air guide device to form a discharge portion. 9. The method of claim 8,
And a filter frame corresponding to the shape of the filter member and forming a mounting space for the filter member. 11. The method of claim 10,
A supporting device positioned on an inner peripheral side of the filter frame and supporting the filter member; And
And a lever device for supporting the lower surface of the support device and moving the support device up and down by rotation.

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