JP2008180456A - Range hood - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a range hood provided with a blower unit improved so as to suppress noise due to turbulence of contaminated air in an exhaust box of an exhaust device. <P>SOLUTION: The blower unit 2 installed on a hood part 1 is provided with the exhaust box 2a attached on a top plate 1a so as to communicate with a communication opening 7 of the hood part 1, and the exhaust device 2b internally provided in the exhaust box 2a. A directional member 23 for guiding a flow of contaminated air G flowing into the exhaust box 2a from the communication opening 7 through a grease filter 9 provided in the hood part 1, toward a suction opening 22 side of a fan casing 16 of the exhaust device 2b, is provided in the exhaust box 2a. The directional member 23 is bent along an opening upper part rim of the suction opening 7, and it is formed into a substantially inverted U-shape as seen from the front facing the top plate 1a of the hood part 1. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention is disposed above a cooking device such as a gas stove, an electric stove, or an electromagnetic induction heating type cooking heater (so-called IH cooking heater), and generates waste gas, oil smoke, steam (steam from a pan, etc.) generated during cooking. The present invention relates to a range hood for sucking and capturing contaminated air (contaminant) and exhausting it outdoors, and more particularly, to an improvement of a blower unit mounted on a thin hood portion that opens downward.

  The range hood has a boot-type hood with a deep trapping space for contaminated air, a flat hood with a shallow trapping space, and an exhaust device in the hood. Various forms are known, such as what is installed and what is installed on the hood part. This form is supposed to be designed in consideration of the design that matches the system kitchen.

A range hood with a flat hood is known to have a blower unit installed on the top of the hood that has a shallow capture space that opens downwards. A slim type range hood has been developed in which the hood portion that most affects the capture of contaminated air is made very thin (see, for example, Patent Document 1 and Patent Document 2).
This slim type range hood has been proposed in a variety of kitchen layouts that incorporate Western styles in recent years. It attracts attention because it can implement a novel design as a hood.

In such a slim type range hood, as shown in FIG. 1 of Patent Document 1, a blower unit is installed on a flat hood portion.
The blower unit includes an exhaust box mounted on the top plate of the hood portion, and an exhaust device is installed vertically in the exhaust box.
The exhaust device has a configuration in which an exhaust fan (centrifugal fan or multiblade fan) supported by a fan motor is coaxially accommodated in a fan casing installed vertically in an exhaust box.

By the way, as shown in FIG. 10, the exhaust device 2b of the blower unit 2 that is located on the communication port 7 of the hood portion 1 and is installed on the top plate 1a is located on the kitchen wall K side in the exhaust box 2a. It is located on the rear half side, and is vertically installed in the exhaust box 2a with the suction port 22 of the fan casing 16 facing the front side (cooker side) of the hood portion 1.
As a result, the inflow space 20 of contaminated air G communicating with the inside of the hood portion 1 through the communication port 7 of the hood portion 1 is provided on the front half side of the exhaust box 2a on the front side of the exhaust device 16 (suction port 22) (patented) (Referred to as the upstream air flow path 19 in Document 1), and after the contaminated air G passing through the grease filter 9 provided in the hood portion 1 once flows into the inflow space 20, the fan The air is sucked into the fan casing 16 from the suction port 22 of the casing 16 and exhausted outdoors.

And the grease filter provided in the food | hood part 1 located in the lower side of a connection port changed to the glass filter currently disclosed by patent document 2, and recently, it is a metal filter currently disclosed by patent document 1 Is becoming mainstream.
In particular, as shown in FIG. 4, multiple rows of slits 11 are provided in one direction perpendicular to the suction direction Z of the exhaust device 2 b at a pitch interval of several millimeters on the thin metal plate 9 a. And the air collision piece part 12 which is the plane part divided by this slit 11 mutually is directed to the one side surface direction of the metal thin plate 9a formed slightly smaller than the downward opening of the hood part 1, and The vent hole 13 that is inclined upward toward the front side of the hood part 1 is opened without leaving a flat surface by cutting and raising the hood part 1 toward the front side (cooker side). The slot filter formed by this is becoming mainstream.

As described above, the slot filter has a structure (form) in which the vent hole 13 through which the contaminated air G passes is opened so as to incline upward toward the front side (cooker side) of the hood portion 1. Therefore, as shown in FIG. 4B, when the contaminated air G passes, it is guided so as to be meandered by the air collision piece 12 that refracts without passing straight through the vent hole 13.
Thereby, high capture | acquisition efficiency, such as the fats and oils contained in the contaminated air G, can be acquired with comparatively little ventilation resistance. Therefore, the collection efficiency of oil and fat is higher than punching metal.

In addition, the slot filter formed in this way has a long-term stable adsorption function such as ventilation resistance and oil collection efficiency required for filters compared to filters such as wire mesh, lath mesh, or punching metal. Can continue well.
In addition, the slot filter is formed by cutting and raising the ventilation holes in a thin metal plate. Therefore, the slot filter has features such as excellent cleaning and other maintainability compared to a filter made of lath or wire mesh. Have.

  In addition, as a thing with high oil-and-fat collection property as a grease filter, the glass filter currently formed using the chemical fiber etc. which are disclosed in patent document 2 exists, but this glass filter Is flammable and cannot be used for a range hood, particularly when a gas stove or electric stove is used as a cooking device.

In addition, in the slim type range hood, as shown in FIG.
A rectifying plate is provided along the downward opening edge of the hood portion (hood) on the lower side of the glass filter.

This rectifying plate is for improving the exhaust efficiency of polluted air, as described in paragraph No. 0019 of the specification of Patent Document 2.
That is, as shown in FIG. 10, by providing the current plate 10, a suction force is generated between the current plate 10 and the downward opening edge of the hood portion 1 to suck the contaminated air G into the hood portion 1. A suction gap S for ensuring the above is ensured.
As a result, the contaminated air rising toward the hood part from the cooking device or cooking pan is sucked into the hood part from the suction gap that opens along the downward opening edge of the hood part. Preventing the emission of contaminated air to the outside of the hood and improving the efficiency of capturing (capturing) contaminated air.
Japanese Patent Laying-Open No. 2005-106426 (see paragraph numbers 0030 and 0033 and FIG. 1) Japanese Patent Laying-Open No. 2005-282872 (see paragraph numbers 0014 to 0019 and FIG. 1)

By the way, as shown in FIG. 4 and FIG. 10, when the contaminated air that flows in so as to be sucked into the hood portion passes through the grease filter, the flow is bent so as to meander, and the communication port of the hood portion 1. 7 tends to flow into the exhaust box 2a so as to go to the front plate side of the exhaust box 2a (the direction opposite to the suction port 22 of the fan casing 16).
As a result, the direction of the flow is changed so that a part of the contaminated air G flowing in so as to be sucked into the exhaust box 2a is sucked into the fan casing 16 from the suction port 22, as shown in FIG. Instead, the air passes through the suction port 22 as it is and rises along the front plate of the exhaust box 2a toward the upper surface plate 19 of the exhaust box 2a. Thereafter, the air flows in the direction of the suction port 22 and flows into the fan casing 16 from the suction port 22.
At this time, the flow of the contaminated air G rising toward the upper surface plate 19 of the exhaust box 2a and then descending toward the suction port 22 side, and the contaminated air G flowing into the exhaust box 2a from the communication port 7 The flow interferes with each other to cause a large turbulent flow (interference flow) in the exhaust box 2a. This turbulent flow becomes a large air resistance and comes into contact with the front plate and top plate of the exhaust box, and the contact sound at this time becomes noise transmitted to the entire range hood and pulsating abnormal noise on the kitchen side. There was a problem that it occurred, and the improvement was desired.

  Therefore, the present invention was devised in order to solve the above-mentioned problems, and polluted air that passes through the grease filter in a meandering manner and flows into the exhaust box of the blower unit from the communication port of the hood portion. The range hood is configured to exhaust the air through the exhaust duct from the suction port of the exhaust device installed vertically in the exhaust box, and generates turbulent flow of contaminated air in the exhaust box. It is providing the range hood provided with the air blower unit which can be suppressed.

In order to solve the above problems, the present invention includes a hood portion that opens downward, and a blower unit that is installed on a top plate of the hood portion, and the hood portion is in communication with the blower unit. The communication board is provided with a grease filter on the lower side of the communication opening, and the blower unit is mounted on the top board so that the front first half is communicated with the communication opening. An exhaust box having a substantially quadrangular shape in a plan view, and an exhaust device installed vertically in the rear half of the exhaust box except for the front half of the front communicating with the communication port. Contaminated air that passes through the grease filter so as to meander and is sucked into the inflow space of the exhaust device in the exhaust box from the communication port. A range hood and a suction port of forward opened in the fan casing to evacuate outdoors through an exhaust duct connected to the fan casing,
Directivity for guiding the flow of the contaminated air that flows into the inflow space of the exhaust device in the exhaust box so as to be sucked from the communication port toward the opening direction of the suction port of the fan casing. A range hood is provided with a member.
Here, it is preferable that a baffle plate is provided on the lower side of the grease filter so as to secure a suction gap for sucking contaminated air into the hood portion between the downward opening edge of the hood portion. It will be a thing.

According to such a configuration, the contamination that passes through the grease filter in a meandering manner and is sucked into the inflow space of the exhaust box of the blower unit from the communication port of the hood portion (flows in). The air flow is promptly guided to the opening direction of the suction opening of the fan casing by the directional member, and flows into the fan casing from the suction opening.
As a result, the contaminated air that passes through the grease filter in a meandering manner and continuously flows into the inflow space of the exhaust box from the connection port does not cause turbulent flow that is disturbed due to flow interference or the like, and from the suction port. Quickly flows into the fan casing.

  In the present invention, the directivity member has a width from the front plate of the fan casing where the suction port of the exhaust device is opened to the front plate of the exhaust box, and the opening of the suction port. The range hood is characterized by being formed in a substantially reverse U-shape when viewed from the front so as to be curved along the upper edge and extend toward the top plate of the hood.

  According to such a configuration, as described above, the polluted air flowing in the direction of the front plate in the inflow space of the exhaust box is substantially reversed in the front view along the upper edge of the opening of the suction port. The directional member formed in a letter shape is promptly guided in the opening direction of the suction opening of the fan casing, and flows into the fan casing from the suction opening.

  And in this invention, the said directional member has the width | variety which reaches between the both-sides board of the said exhaust box in the said inflow space, and is located from the front board of the said fan casing located in the opening upper edge of the said suction inlet. The range hood is formed in a substantially arc shape in a side view curved downward so as to reach the front plate of the exhaust box.

  According to such a configuration, as described above, the contaminated air flowing in the direction of the front plate in the inflow space of the exhaust box is exhausted from the front plate of the fan casing located at the upper edge of the opening of the suction port. By a substantially arc-shaped directional member that is curved downward toward the front plate of the box, it is quickly guided in the opening direction of the fan casing suction port and flows into the fan casing from the suction port. Is done.

  Further, in the present invention, the front opening is formed so that the directional member formed in a substantially reverse U-shape in a front view or a substantially arc shape in a side view can open and close the front opening of the exhaust box. It is in the range hood characterized by being attached to and supported by a front lid attached to the hood.

  According to such a configuration, when performing maintenance such as removing the directional member from the exhaust box of the blower unit and cleaning it, the front lid that closes the front opening of the exhaust box so as to be opened and closed is removed from the exhaust box. Thus, the directional member can be removed from the exhaust box.

The range hood of the present invention is configured as described above, so that it passes through the grease filter in a meandering manner and is sucked into the inflow space of the exhaust box of the blower unit from the communication port of the hood portion. The flow of contaminated air is guided in the opening direction of the suction opening of the fan casing by a directional member formed in a desired shape such as a substantially U-shaped in a reverse direction in a front view or a substantially arc shape in a side view. Then, it quickly flows into the fan casing from the suction port.
Thereby, generation | occurrence | production of the turbulent flow by interference of the flow of the contaminated air in an exhaust box can be suppressed. Therefore, it can be expected that the level of noise accompanying turbulent flow or pulsating abnormal noise is reduced to a noise value dB (A) that the cook does not care about.

Further, according to the range hood of the present invention, the directional member is attached to and supported by the front lid attached to the front opening so as to close the front opening of the exhaust box so that it can be opened and closed. For example, the directional member can be removed from the exhaust box by removing the front cover from the exhaust box.
Thereby, the effect that it is simple also in the detachability of the directional member at the time of maintenance can be expected.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.
FIG. 1 is a longitudinal side view showing a range hood of the present invention provided with a directivity member according to the first embodiment, FIG. 2 is a longitudinal sectional view, and FIG. 3 is a first view together with a front lid. It is a perspective view when the food | hood part is seen from diagonally upward in the state which removed the directivity member which concerns on embodiment from an exhaust box.
There are two types of range hoods, a wall-mounted type and a ceiling-mounted type (island type). In this embodiment, a wall-mounted range hood will be described as an example. In this embodiment, in the direction of the range hood as viewed from the side of the cook who performs cooking (kitchen side), the arrow F is the front side of the hood part, the arrow R is the rear side of the hood part, and the arrow X is the hood part. The arrow Y indicates the right side of the hood part (see FIG. 3).

≪Configuration of range hood≫
The range hood A is installed almost directly above a cooking utensil (not shown), and sucks and captures contaminated air G such as oily smoke, water vapor, hot air, and waste gas generated during cooking, and exhausts it outside through an exhaust duct 3. It is configured as follows.
As shown in FIGS. 1 and 3, the range hood A is configured by mounting a blower unit 2 on a flat (thin) hood portion 1.
Further, as shown in FIG. 1, the range hood A is a curtain formed so as to cover the blower unit 2 and the exhaust duct 3 from the top plate 1a of the hood portion 1 to the ceiling K-2 of the kitchen. The plate 4 is provided so that it can be removed as appropriate.

≪Food part composition≫
As shown in FIG. 1, the hood portion 1 is formed in a flat box shape that opens downward. And
As shown in FIG. 1 and FIG. 3, the hood portion 1 includes an operation switch portion 5 on the front surface portion 1 b located on the front side F that is the cooker side.
The operation switch unit 5 switches on / off the operation of an exhaust device 2b, which will be described later, and a light bulb provided on the rear side R (kitchen wall surface K-1 side) of the downward opening of the hood unit 1 Touch or push type switches (not shown) for switching on / off of the lighting 6 are provided.

Moreover, the food | hood part 1 is provided with the connection port 7 in the top plate 1a as shown in FIG. 1 and FIG.
This connection port 7 is for communicating the inside of the exhaust box 2a (described later inflow space 20) and the hood portion 1 with the blower unit 2 and has a predetermined opening area at a substantially central portion of the top plate 1a. Has been established.
As shown in FIG. 1, the hood portion 1 includes a hood cover 8 on the lower side of the communication port 7 so as to partition the downward opening side and the communication port 7 side, and a grease filter 9 is provided on the hood cover 8. It is provided so that it can be detached and removed. As a result, when the contaminated air G passes through the grease filter 9, the oil and fat contained in the contaminated air G is separated and captured (see FIG. 4 described later).

  Further, as shown in FIG. 1, the hood portion 1 is provided with a current plate 10 on the lower side of the grease filter 9 so as to secure a suction gap S between the hood portion 1 and the downward opening edge. As a result, the contaminated air G rising from the cooking device or cooking pan is sucked into the hood portion 1 from the suction gap S along the rectifying plate 3.

≪Grease filter configuration≫
FIG. 4 is a perspective view and an enlarged cross-sectional view showing an example of the positional relationship between the grease filter and the exhaust device of the blower unit.
The grease filter 9 is made of a thin metal plate made of an aluminum plate or stainless steel plate having excellent corrosion resistance and the like, and has a substantially rectangular shape in plan view having a predetermined area larger than at least the opening area of the communication port 7 of the hood portion 1. Is formed.
The grease filter 9 is a slot filter formed as described in the technical field.
That is, as shown in FIG. 4, the grease filter 9 has a plurality of rows in one direction perpendicular to the suction direction Z of the exhaust device 2 b at a pitch interval of several millimeters on a thin metal plate 9 a. The slit 11 is provided. And the air collision piece part 12 which is a plane part divided by this slit 11 toward the direction of one side of the metal thin plate 9a formed slightly smaller than the downward opening of the hood part 1, In addition, the vent hole 13 that is inclined upward toward the front side of the hood 1 without leaving a flat surface portion by cutting and raising so as to bend and incline toward the front side F (cooker side) of the hood 1. It is open.

<Composition of current plate>
The rectifying plate 10 has substantially the same shape as the opening shape of the downward opening edge of the hood portion 1 and is formed to be slightly smaller than the opening area. The current plate 10 is supported by the hood cover 8 via front and rear support members (not shown) so as to be rotatable about the rear side and detachable.
Thereby, when wash | cleaning the grease filter 9, the baffle plate 10 is rotated downward toward the rear side R (kitchen wall surface K-1 side) of the food | hood part 1. As shown in FIG. Or it can be removed.

≪Blower unit configuration≫
The blower unit 2 is configured as described in the technical field.
That is, as shown in FIG. 1, the blower unit 2 is positioned vertically on the rear half side excluding the exhaust box 2a and the front half part communicating with the communication port 7 of the hood part 1 in the exhaust box 2a. And an exhaust device 2b provided therein.

≪Exhaust box configuration≫
As shown in FIGS. 1 and 3, the exhaust box 2a is screwed on the top plate 1a so that the front half communicates with the communication port 7 opened in the top plate 1a of the hood portion 1. It is formed in a substantially quadrangular shape when viewed in a longitudinal section.
As shown in FIG. 3, the exhaust box 2 a is configured such that the front surface is opened and the front opening 14 is closed with a front lid 15 so as to be opened and closed. Thus, after removing the curtain plate 4, the front cover 15 is removed from the exhaust box 2a, so that an exhaust fan described later can be taken out from the fan casing. That is, the front opening 14 of the exhaust box 2a can be opened when the exhaust fan is cleaned or when the inside of the fan casing is cleaned.

≪Exhaust system configuration≫
As shown in FIG. 1, the exhaust device 2 b includes an exhaust fan (a centrifugal fan, a centrifugal fan, and a fan casing 16 provided with a connection cylinder to which the exhaust duct 3 is connected at the upper surface of the circumference. The multi-blade fan) 17 is coaxially accommodated.

≪Fan casing configuration≫
The fan casing 16 is formed by fixing the front side plate 16b and the rear side plate 16c to the front and back of the volute-shaped body portion 16a by welding or the like. And this fan casing 16 can be detachable from the upper opening connected to the exhaust duct 3 on the upper surface plate 19 of the exhaust box 2a by the relationship between the latching claw and the latching hole (not shown), or It is attached by screwing or the like, and is positioned vertically on the rear half side excluding the inflow space 20 of the exhaust air G secured on the front half side communicating with the communication port 7 of the hood part 1 in the exhaust box 2a. (See FIG. 1).
As a result, the fan casing 16 is disposed in the exhaust box 2a in a front-facing state in which the suction port 22 formed by the bell mouth 21 being detachably attached by screwing or the like is opened horizontally toward the inflow space 20. (See FIG. 3).

  And the range hood A of this embodiment is equipped with the directional member 23 in the inflow space 20 of the contaminated air G connected to the inside of the hood part 1 through the communication port 7 of the hood part 1 of the exhaust box 2a of the blower unit 2. ing.

<< Configuration of Directional Member of First Embodiment >>
Next, the directional member according to the first embodiment will be described with reference to FIGS. 1 to 3.
After passing through the grease filter 9, the directional member 23 converts the flow of the contaminated air G that is sucked into the inflow space 20 of the exhaust box 2 a from the communication port 7 into the opening of the suction port 22 of the fan casing 16. It is for guiding in the direction.

  As shown in FIGS. 1 and 2, the directivity member 23 according to the first embodiment extends from the front plate 16a of the fan casing 16 in which the suction port 22 is opened to the inner surface of the front cover 15 of the exhaust box 2a. A so-called metal strip having a predetermined plate width is used, so-called in the direction of the top plate 2a of the hood portion 1 along the upper opening edge of the suction port 22 (the ring outer peripheral upper edge of the bell mouth 21). It is bent and formed in a substantially reverse U shape in front view so as to extend in the downward direction.

And in this embodiment, as shown in FIG. 1 and FIG. 3, the directivity member 23 currently formed in the substantially reverse U-shape by the front view is used for the exhaust box 2a which comprises the air blower unit 2 in this embodiment. The front cover 15 is supported by welding or by screwing.
Thereby, after removing the curtain 4, the directional member 23 can be taken out from the inflow space 20 of the exhaust box 2a by removing the front cover 15 from the front opening 14 of the exhaust box 2a ( (See FIG. 3).

As described above, according to the range hood A according to the present embodiment in which the directional member 23 formed in a substantially reverse U-shape in the front view is provided in the exhaust box 2a of the blower unit 2, As shown in FIG. 1, the flow of the contaminated air G that passes through the grease filter 9 so as to meander and is sucked from the communication port 7 of the hood portion 1 toward the inflow space 20 of the exhaust box 2a is The directivity member 23 is guided along the inner surface of the directional member 23 having a substantially U-shape in the reverse direction to the opening direction of the suction port 22 of the fan casing 16, and quickly flows into the fan casing 16 from the suction port 22. (See FIGS. 1 and 2).
Thereby, the contaminated air G flowing into the inflow space 20 of the exhaust box 2a from the communication port 7 of the hood portion 1 does not cause turbulence due to a change in the flow direction in the inflow space 20 and the like from the suction port 22. The air immediately flows into the fan casing 16 and is exhausted to the outside through the exhaust duct 3.

<< Configuration of Directional Member of Second Embodiment >>
Next, the directional member according to the second embodiment will be described with reference to FIGS. 5 and 6.
FIG. 5 is a vertical side view showing the range hood of the present invention provided with the directional member according to the second embodiment, and FIG. 6 shows the directional member according to the second embodiment together with the front cover as an exhaust box. It is a perspective view when the food | hood part is seen from diagonally upward in the state removed from.
As shown in FIGS. 5 and 6, the directivity member 23-1 according to the second embodiment has a width extending between both side plates 24 of the exhaust box 2 a constituting the blower unit 2 and suction. It is substantially in a side view curved downward so as to reach the inner surface of the front cover 15 of the exhaust box 2a from the front plate 16a of the fan casing 16 located at the upper edge of the opening of the mouth 22 (the ring outer periphery upper edge of the bell mouth 21). It is formed in an arc shape.

In the present embodiment, the directivity member 23-1 formed in a substantially arc shape in a side view is supported on the front lid 15 of the exhaust box 2a by welding, screwing, or the like. Yes.
Thereby, after removing the curtain 3, the directional member 23-1 can be taken out from the inflow space 20 of the exhaust box 2a by removing the front cover 15 from the front opening 14 of the exhaust box 2a. (See FIG. 6).

As described above, according to the range hood A according to the present embodiment in which the directional member 23-1 formed in a substantially arc shape in the side view is provided in the exhaust box 2 a of the blower unit 2, FIG. As shown, the flow of the contaminated air G that passes through the grease filter 9 so as to meander and is sucked from the communication port 7 of the hood 1 toward the inflow space 20 of the exhaust box 2a is It is guided in the direction of the suction port 22 of the fan casing 16 along the substantially circular arc inner surface of the directivity member 23-1 (see FIG. 5).
As a result, the contaminated air G continuously flowing into the inflow space 20 of the exhaust box 2a is promptly flowed into the fan casing 16 from the suction port 22 without causing turbulent flow that is disturbed by flow interference or the like. The air is exhausted to the outside through the exhaust duct 3.

  FIG. 7 is a graph showing the power spectrum at the time of 50 Hz operation obtained by the noise test in this example, and FIG. 8 is a graph showing the power spectrum at the time of 60 Hz operation obtained by the noise test in this example. is there.

Example 1
Next, as shown in FIG. 1, the directivity member 23 formed in a substantially reverse U-shape is exhausted with respect to the suction port 22 of the fan casing 16 of the exhaust device 2 b constituting the blower unit 2. In order to investigate the effect of reducing the noise value dB (A) due to the inflow of the contaminated air G into the exhaust box 2a when installed inside the box 2a, a noise test was performed based on the following test conditions. . The results are shown in Tables 1 to 3.
Test conditions a. Voltage: 100V 50Hz / 60Hz
b. Exhaust fan feather shape: Centrifugal fan (sirocco fan)
c. Exhaust: Ceiling direction d. Temperature (room temperature): 24.0 ° C
e. Atmospheric pressure (room pressure): 1007.2 hPa (755.5 mmHg)
f. Air density: 1.174 kg / m ³
This noise test is based on a JISC9603 ventilation fan.

Example 2
Further, as shown in FIG. 5, the directivity member 23-1 that is formed in a substantially arc shape in a side view is formed with respect to the suction port 22 of the fan casing 16 of the exhaust device 2 b that constitutes the blower unit 2. In order to investigate the effect of reducing the noise value dB (A) associated with the inflow of the contaminated air G into the exhaust box 2a when installed in the exhaust box 2a, the noise is based on the same test conditions as in the first embodiment. Perform a test. The results are also shown in Tables 1 to 3.

Comparative Example 1
And as a comparative example 1, it tested by the same test conditions as Example 1 and Example 2 using the range hood shown in FIG.

  As is clear from Table 3, it can be seen that both Example 1 and Example 2 exhibit a low noise value dB (A) when compared with Comparative Example 1 when operating at 50 Hz and when operating at 60 Hz. .

Further, as can be seen from Table 1, the noise value dB (A) measured in this noise test varies in the respective air volumes (m ³ / h) in Comparative Example 1, Example 1 and Example 2, Since the maximum air volume (m ³ / h) is different, accurate measurement is difficult.
Therefore, the evaluation was performed using a non-noise level showing a substantially constant value by the blower unit, particularly the exhaust device, regardless of the air volume (m ³ / h), the static pressure (Pa), and the rotation speed (rpm). This non-noise level is shown in Table 4.
As is clear from Table 4, it can be seen that the noise values of both Example 1 and Example 2 are lower than those of Comparative Example 1. In particular, it can be seen that the reduction effect is higher when the directional member formed in the substantially arc shape of Example 2 is attached.

  Further, as is apparent from the power spectrum at the time of 50 Hz operation shown in FIG. 7 and at the time of 60 Hz operation shown in FIG. 8, both Example 1 and Example 2 are almost entirely compared with Comparative Example 1. It can be seen that the noise value dB (A) is reduced.

Therefore, as is clear from the result of the noise test, the directivity member 23 of Example 1 and the directivity member 23-1 of Example 2 are provided in the exhaust box 2a of the blower unit 2 in this embodiment. The range hood A has a lower noise value dB (A) than the conventional range hood of Comparative Example 1 shown in FIG.
After passing through innumerable ventilation holes 13 of the grease filter 9 inclined upward toward the front side F of the hood part 1 so as to meander, the inside of the exhaust box 2a of the blower unit 2 from the communication port 7 of the hood part 1 The contaminated air G flowing into the directional member 23 and the embodiment of the first embodiment does not rise toward the upper surface plate 19 of the exhaust box 2a as in the range hood of the first comparative example shown in FIG. The two directivity members 23-1 promptly guide the fan casing 16 toward the suction port 22 (bell mouth 21).
Thereby, unlike the range hood of the comparative example 1 shown in FIG. 10, a turbulent flow does not arise in the exhaust box 2a. In particular, as shown in FIG. 5, it is formed in a substantially arc shape in a side view curved from the inside of the front cover 15 that closes the front opening 14 of the exhaust box 2 a toward the upper edge of the opening of the suction port 22 of the fan casing 16. In the directivity member 23-1 of the second embodiment, the noise value dB (A) accompanying the air resistance of the contaminated air G generated in the exhaust box 2a can be effectively reduced.

Moreover, in the range hood A of this embodiment, as shown in Table 1, compared with the comparative example 1, both Example 1 and Example 2 have acquired the high air volume (m < ³ > / h). .
This is because the polluted air G flowing into the inflow space 20 of the exhaust box 2a from the communication port 7 of the hood 1 is provided in the distribution space 20 of the directional member 23 of the first embodiment and the second embodiment. It is considered that the inflow resistance (air resistance) of the contaminated air G in the inflow space 20 is reduced by being quickly guided toward the suction port 22 of the fan casing 16 by the directional member 23-1. It is done.
Thereby, the range hood A of this embodiment can also be expected to have an effect of improving the exhaust capability of the contaminated air G sucked and captured by the hood unit 1 to the outside.

<< Configuration of Directional Member of Third Embodiment >>
Next, a directional member according to the third embodiment will be described with reference to FIG.
FIG. 9 is a longitudinal side view showing a range hood of the present invention provided with a directional member according to the third embodiment.
As shown in FIG. 9, the directivity member 23-2 according to the third embodiment has a suction direction Z of the fan casing 16 from the inner surface of the front cover 15 that closes the front opening 14 of the exhaust box 2a (see FIG. 4). It is formed in a shape that protrudes toward (see).

Although not shown, the directional member 23-2 is formed in a substantially horizontally long rectangular shape in plan view having a length extending between both side plates 24 of the exhaust box 2a.
Further, as shown by a two-dot chain line in FIG. 9, the projecting shape of the directional member 23-2 is particularly limited, such as being formed in an upward inclined shape or an upward curved shape toward the suction port 22. It is not something.

Note that the specific configuration of the embodiment of the present invention is not limited to the above-described embodiment, and there are design changes and the like within a scope not departing from the gist of the present invention described in claims 1 to 4. Are also included in the present invention.
For example, the directivity member 23-1 detailed in the second embodiment is separated from the front plate 16 a of the fan casing 16 as shown by a two-dot chain line in FIG. 9 in the third embodiment. You can also.
Further, the directivity members 23 and 23-1 of the first embodiment and the second embodiment are formed in a shape (form) in which the open lower end side is extended to reach the top plate 1 a of the hood portion 1. be able to.
Further, the directivity members 23, 23-1 and 23-2 of the first to third embodiments are appropriately removed from both side plates 24 across the side plates 24 of the exhaust box of the blower unit 2. It can also be supported so as to be detachable.

FIG. 3 is a longitudinal side view showing the range hood of the present invention provided with the directional member according to the first embodiment. It is the II-II sectional view taken on the line of FIG. It is a perspective view when a food | hood part is seen from diagonally upward in the state which removed the directivity member which concerns on 1st Embodiment from the exhaust box with the front cover. An example of a grease filter (slot filter) is shown, (a) is a perspective view showing the directionality and positional relationship with the exhaust device, and (b) is an enlarged cross-sectional view taken along the line bb of (a). . It is a vertical side view which shows the range hood of this invention provided with the directivity member which concerns on 2nd Embodiment. It is a perspective view when a food | hood part is seen from diagonally upward in the state which removed the directivity member which concerns on 2nd Embodiment from the exhaust box with the front cover. It is a graph which shows the power spectrum at the time of the 50-Hz driving | operation obtained by the noise test in this embodiment. It is a graph which shows the power spectrum at the time of 60Hz operation obtained by the noise test in this embodiment. It is a vertical side view which shows the range hood of this invention provided with the directivity member which concerns on 3rd Embodiment. It is a vertical side view which shows an example of the conventional range hood.

Explanation of symbols

A Range hood 1 Hood 1a Top plate 2 Blower unit 2a Exhaust box 2b Exhaust device 3 Exhaust duct 7 Contact port 9 Grease filter (slot filter)
9a Metal thin plate 10 Current plate 11 Slit 12 Air collision piece 13 Vent 14 Front opening (exhaust box)
15 Front cover 16 Fan casing 17 Exhaust fan (centrifugal fan)
20 Inflow space (exhaust box)
22 Suction port (fan casing)
23, 23-1, 23-2 Directional member S Suction gap K-1 Kitchen wall

Claims (5)

A hood part that opens downward, and a blower unit installed on the top plate of the hood part,
The hood includes a communication port for communicating with the blower unit in the top plate, and includes a grease filter below the communication port,
The blower unit has an exhaust box having a substantially rectangular shape in a longitudinal sectional view attached to the top plate so as to communicate the front first half with the communication port, and the communication port in the exhaust box. An exhaust device installed in a vertical position located in the rear half of the rear excluding the front front half that communicates,
Contaminated air that passes through the grease filter so as to meander and is sucked into the inflow space secured on the front side of the exhaust device in the exhaust box from the communication port, A range hood configured to exhaust to the outside through an exhaust duct connected to the fan casing from a forward-facing suction port opened in the fan casing,
A directional member for guiding the flow of the contaminated air flowing into the inflow space in the exhaust box so as to be sucked from the communication port toward the opening direction of the suction port of the fan casing; A range hood characterized by   The directivity member has a width from the front plate of the fan casing in which the suction port is opened to the front plate of the exhaust box in the inflow space, and along the upper edge of the suction port opening. The cooker hood according to claim 1, wherein the cooker hood is formed in a substantially reverse U-shape in front view so as to extend toward the top plate of the hood portion.   The directivity member has a width extending between both side plates of the exhaust box in the inflow space, and is located in front of the exhaust box from the front plate side of the fan casing located at the upper edge of the opening of the suction port. The range hood according to claim 1, wherein the range hood is formed in a substantially arc shape in a side view curved downward so as to reach the face plate.   4. The directional member is attached and supported by a front lid attached to the front opening so as to close the front opening of the exhaust box so as to be openable and closable. Range hood according to item.   5. The rectifying plate is provided below the grease filter so as to secure a suction gap between the downward opening edge of the hood portion and the hood portion. The range hood described in 1.

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