JP4096243B2 - Ventilation duct - Google Patents

Description

【００２８】
図６〜図８は、実験１における実験結果を図示したもので、前述した各設定条件での吹出口２０における調温空気の風速分布態様を示している。すなわち図６は、曲面壁部３２の曲率半径Ｒ＝２０ｍｍとした前記第１通気ダクト３０Ａ(図５(ａ))の４タイプにおける各吹出口２０の風速分布態様を示し、また図７は、曲面壁部３２の曲率半径Ｒ＝５０ｍｍとした前記第２通気ダクト３０Ｂ(図５(ｂ))の４タイプにおける各吹出口２０の風速分布態様を示し、更に図８は、曲面壁部３２の曲率半径Ｒ＝８０ｍｍとした前記第３通気ダクト３０Ｃ(図５(ｃ))の４タイプにおける各吹出口２０の風速分布態様を示したものである。
【００２９】
また表２は、図５および図６〜図８に例示した実験１の実験結果に基き、前記第１〜第３の各通気ダクト３０Ａ,３０Ｂ,３０Ｃにおける４タイプの評価結果を示した一覧表である。なお表２の下部に、図１１〜図１６に例示した従来の３タイプの各通気ダクト１０を、前記▲１▼〜▲３▼の評価方法によって評価した場合を併記した。すなわち、図１１および図１２に示した従来の通気ダクト１０では、前記▲１▼〜▲３▼の評価を合計した総合評価が７.５点となり、同様に図１３および図１４に示した従来の別の通気ダクト１０では総合評価が７.５となり、図１５および図１６に示した従来の更に別の通気ダクト１０では総合評価が８.５となった。
【００３０】
【表２】

【００３１】
前記実験１では、曲面壁部３２の曲率半径Ｒ＝２０ｍｍに設定した第１通気ダクト３０Ａにおいて４タイプ、曲面壁部３２の曲率半径Ｒ＝５０ｍｍに設定した第２通気ダクト３０Ｂにおいて４タイプ、曲面壁部３２の曲率半径Ｒ＝８０ｍｍに設定した第３通気ダクト３０Ｃにおいて４タイプ、合計１２種類の通気ダクトにおける配風性能の実験を行なった。これら１２種類の各通気ダクト３０に対する各々の総合評価は８.５(最低)〜１３.０(最高)の範囲となり、何れの通気ダクトにあっても図１１〜図１６に示した従来の各通気ダクト１０と同等または良好な総合評価が得られ、その殆どは従来の各通気ダクト１０よりも良好となった。換言すると、前記第２壁部１６において前記吹出口２０の開口領域に臨む背面部位を、該第２壁部１６から該吹出口２０の側へ湾曲的に延在する曲面壁部３２と、この曲面壁部３２の端縁から該吹出口２０に沿って延在する平面壁部３４とで形成した実施例の通気ダクト３０は、これら曲面壁部３２および平面壁部３４の形成位置に殆ど関係なく、少なくとも図１１〜図１６に示した従来の各通気ダクト１０よりも、配風性能の向上が図られていると評価できる。
【００３２】
前記吹出口２０と調温空気の適正風速領域Ｗとの面積比率Ｂ／Ａに関しては、表２から明らかなように、１２種類の殆どの通気ダクトにおいて、従来よりも良好な結果が得られた。そして、第１〜第３の各通気ダクト３０Ａ,３０Ｂ,３０Ｃの何れにも共通する傾向として、該曲面壁部３２の形成位置をダクトの上流側(第１形成位置)に設定する程に調温空気の適正風速領域Ｗを拡大化することができ、更には第１通気ダクト３０Ａよりも、第２通気ダクト３０Ｂおよび第３通気ダクト３０Ｃの方がより良好な結果が得られた。このことから、調温空気の適正風速領域Ｗの拡大化を図る場合には、曲面壁部３２の曲率半径Ｒを５０ｍｍまたは８０ｍｍに設定した場合に良好な結果が得られたことから、実際には該曲率半径Ｒ＝４０〜９０ｍｍ程度とするのが適当である。
【００３３】
前記吹出口２０に対する調温空気の適正風速領域Ｗの位置に関しては、表２から明らかなように、第１〜第３の各通気ダクト３０Ａ,３０Ｂ,３０Ｃの何れにも共通する傾向として、曲面壁部３２の形成位置を前記第１形成位置とした場合に、適正風速領域Ｗが吹出口２０の中央または略中央となった。しかしながら、折曲連接部分３６の設定位置を前記第３形成位置または第４形成位置とした場合には、適正風速領域Ｗが吹出口２０の左側または左端に偏倚してしまう。このことから、調温空気の適正風速領域Ｗの位置を吹出口２０の中央または略中央としたい場合には、ダクトの長手方向における折曲連接部分３６の設定位置を、吹出口２０の上流側端縁３８から３０ｍｍ離間した位置(第１位置Ｐ１)と、該吹出口２０の上流側端縁３８から６０ｍｍ離間した位置(第２位置Ｐ２)との間とすることが適当である。
【００３４】
前記圧損値に関しては、表２から明らかなように、第１〜第３の各通気ダクト３０Ａ,３０Ｂ,３０Ｃの何れにも共通する傾向として、曲面壁部３２の形成位置を前記第１形成位置に設定した場合が最大となり、逆に該曲面壁部３２の形成位置を前記第４形成位置に設定した場合に最小となる傾向が顕著に現れた。従って、圧損値の軽減化をも考慮する場合には、ダクトの長手方向における折曲連接部分３６の設定位置を、可能な限り前記第２位置Ｐ２に近づけるようにするのが望ましい。
【００３５】
そして、前記▲１▼〜▲３▼の各評価を加算合計した総合評価では、１０点以上となったのは次の設定条件であった。先ず、曲面壁部３２の曲率半径Ｒ＝２０ｍｍに設定した第１通気ダクト３０Ａの場合では、総合評価が１０点以上となる場合はなかった。また、曲面壁部３２の曲率半径Ｒ＝５０ｍｍに設定した第２通気ダクト３０Ｂの場合では、該曲面壁部３２の形成位置を第１形成位置または第２形成位置としたときに、総合評価が夫々１３点および１２点となった。更に、曲面壁部３２の曲率半径Ｒ＝８０ｍｍに設定した第３通気ダクト３０Ｃの場合では、該曲面壁部３２の形成位置を第１形成位置および第２形成位置としたときに、総合評価が夫々１２点および１１点となった。
【００３６】
従って、実験１の結果から、曲面壁部３２の曲率半径Ｒは、前述したように４０〜９０ｍｍ程度が適当であることから、前記ダクト本体１２の出口部分における幅寸法Ｄ(３５ｍｍ)の１.２倍〜２.５倍(１.２Ｄ〜２.５Ｄ)程度に設定するのが望ましいと結論付けができる。
【００３７】
また、ダクトの長手方向における前記折曲連接部分３６の設定位置は、吹出口２０の上流側端縁３８から下流側へ３０ｍｍ離間した前記第１位置Ｐ１と、この第１位置Ｐ１から下流側へ３０ｍｍ離間した(吹出口２０の上流側端縁３８から下流側へ６０ｍｍ離間した)前記第２位置Ｐ２との間とするのが望ましい。換言すると、ダクトの長手方向における前記折曲連接部分３６の設定位置は、吹出口２０の上流側端縁３８から下流側へ、該吹出口２０の横寸法Ｅの０.３倍(０.３Ｅ)に相当する距離だけ離間した第１位置Ｐ１と、この第１位置Ｐ１から下流側へ、前記吹出口２０の横寸法Ｅの０.３倍(０.３Ｅ)に相当する距離だけ離間した第２位置Ｐ２との間とするのが望ましいと結論付けができる。
【００３８】
実験２は、前記曲面壁部３２の曲率半径Ｒを一定とし、かつ該曲面壁部３２の形成位置を一定としたもとで、ダクトの短手方向における平面壁部３４の形成位置を変化させた４タイプに関して夫々配風性能を実験した。すなわち、前記曲面壁部３２の曲率半径Ｒを８０ｍｍとし、ダクトの長手方向における折曲連接部分３６の設定位置を、吹出口２０の上流側端縁３８からの間隔Ｓを３０ｍｍ(前記第１形成位置)とした場合において、図９に示すように、ダクトの短手方向における前記折曲連接部分３６の設定位置を、▲１▼第２壁部１６の延長ラインＬからの間隔Ｈａ(１０ｍｍ)とした第５形成位置、▲２▼延長ラインＬからの間隔Ｈｂ(１５ｍｍ)とした第６形成位置、▲３▼延長ラインＬからの間隔Ｈｃ(２０ｍｍ)とした第７設定位置、▲４▼延長ラインＬからの間隔Ｈｄ(２５ｍｍ)とした第８設定位置、の合計４タイプについて配風性能の実験を行なった。従って、前記第７形成位置位置(間隔Ｈｃ＝２０ｍｍ)に関しては、前記実験１に含まれている。
【００３９】
図１０は、実験２における実験結果を図示したもので、前述した４タイプにおける吹出口２０の風速分布態様を示している。また表３は、図１０に例示した実験結果に基づき、前記▲１▼〜▲３▼の評価方法によって前記４タイプの評価結果を示した一覧表である。
【００４０】
【表３】

【００４１】
前記実験２では、平面壁部３４の形成位置が異なる合計４種類の通気ダクト３０における配風性能の実験を行なった。これら４種類の各通気ダクト３０に対する各々の総合評価は９.５(最低)〜１３.０(最高)の範囲となり、何れの通気ダクト３０にあっても、図１１〜図１６に示した従来の各通気ダクト１０より良好な総合評価が得られた。換言すると、前記第２壁部１６において前記吹出口２０の開口領域に臨む背面部位を、該第２壁部１６から該吹出口２０の側へ湾曲的に延在する曲面壁部３２と、この曲面壁部３２の端縁から該吹出口２０に沿って延在する平面壁部３４とで形成した実施例の通気ダクト３０は、前述したように、これら曲面壁部３２および平面壁部３４の形成位置に関係なく、少なくとも図１１〜図１６に示した従来の各通気ダクト１０よりも配風性能の向上が図られていると評価できる。
【００４２】
そして、ダクトの短手方向における前記折曲連接部分３６の設定位置を、吹出口２０の側に近づける程(前記延長ラインＬとの間隔Ｈを大きくする程)、前記吹出口２０の面積と調温空気の適正風速領域Ｗの面積との面積比率Ｂ／Ａが良好となり(評価▲１▼)、前記吹出口２０における調温空気の適正風速領域Ｗの位置が良好となる(評価▲２▼)。しかしながら圧損値は、これとは逆に、ダクトの短手方向における前記折曲連接部分３６の設定位置を吹出口２０の側に近づける程、大きくなる傾向にある(評価▲３▼)。このことから、ダクトの短手方向における前記折曲連接部分３６の設定位置は、前記第２壁部１６の延長ラインＬから前記吹出口２０の側へ１５ｍｍ離間した前記第３位置Ｐ３と、この第３位置Ｐ３から更に該吹出口２０の側へ１５ｍｍ離間した前記第４位置Ｐ４との間とするのが望ましい。
【００４３】
換言すると、ダクトの短手方向における前記折曲連接部分３６の設定位置は、第２壁部１６の延長ラインＬから前記吹出口２０の側へ、前記ダクト本体１２の出口部分における幅寸法Ｄの０.４倍(０.４Ｄ)程度に相当する距離だけ離間した第３位置Ｐ３と、この第３位置Ｐ３から更に該吹出口２０の側へ、前記ダクト本体１２の出口部分における幅寸法Ｄの０.３倍(０.３Ｄ)程度に相当する距離だけ離間した第４位置Ｐ４との間とするのが望ましいと結論付けができる。
【００４４】
なお本願の通気ダクトは、車両内装部材の裏側に配設されるものに限定されるものではなく、様々な分野において空気等の各種気体を流通案内した後に吹出すのに実施される種々のダクトとして実施可能である。
【００４５】
【発明の効果】
以上説明した如く、本発明に係る通気ダクトによれば、第２壁部において吹出口の開口領域に臨む背面部位を、該第２壁部から該吹出口の側へ湾曲的に延在する曲面壁部と、この曲面壁部の端縁から該吹出口に沿って延在する平面壁部とで形成したことにより、上流側から通入された空気等を前記曲面壁部に沿って移動する過程で前記吹出口の側へ分散状態で変向させ、これにより該吹出口から広く通出させ得る。そして、前記曲面壁部および平面壁部に関連する諸寸法を前述したように設定したことにより、吹出口から吹出す空気等の適正風速領域の拡大化および位置適正化を好適に図り得る利点がある。
また、調温空気の適正風速領域が拡大するために、局部的な風速の変化が減少して吹出し騒音が減少するようになると共に、乗員室内の効率的かつ快適な空調を実施し得る。更には、配風性能の向上を図るに際して、乗員が吹出方向を調整可能としたエアアウトレットを別途装着する場合以外は吹出変向装置や整流網等の別部材を準備する必要がないと共に、ブロー成形技術等により一体成形できるため、製造コストが嵩むこともない等の極めて有益な効果を奏する。
【図面の簡単な説明】
【図１】本発明の好適実施例に係る通気ダクトを一部省略して例示した概略斜視図である。
【図２】図２は図１のII−II線断面図である。
【図３】曲面壁部と平面壁部との折曲連接部分に関し、ダクトの長手方向における設定位置およびダクトの短手方向における設定位置を示した説明図である。
【図４】 (ａ)は、吹出口の開口面積と調温空気の適正風速領域の面積との面積比率を評価する方法を示した説明図であり、(ｂ)は、吹出口に対する調温空気の適正風速領域の位置を評価する方法を示した説明図である。
【図５】 (ａ)は、曲面壁部の曲率半径Ｒ＝２０ｍｍに設定した第１通気ダクトに関し、該曲面壁部の形成位置を変更した４タイプの形態を例示した説明断面図、(ｂ)は、曲面壁部の曲率半径Ｒ＝５０ｍｍに設定した第２通気ダクトに関し、該曲面壁部の形成位置を変更した４タイプの形態を例示した説明断面図、(ｃ)は、曲面壁部の曲率半径Ｒ＝８０ｍｍに設定した第２通気ダクトに関し、該曲面壁部の形成位置を変更した４タイプの形態を例示した説明断面図である。
【図６】図５(ａ)に示した４タイプの各第１通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図７】図５(ｂ)に示した４タイプの各第２通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図８】図５(ｃ)に示した４タイプの各第３通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図９】平面壁部の形成位置を変更した４タイプの通気ダクトの形態を例示した説明断面図である。
【図１０】図９に示した４タイプの各通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図１１】従来の通気ダクトを一部省略して例示した部分斜視図である。
【図１２】 (ａ)は、図１１のＸ−Ｘ線断面図、(ｂ)は、図１１に例示した通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図１３】従来の別の通気ダクトを一部省略して例示した部分斜視図である。
【図１４】 (ａ)は、図１３のＹ−Ｙ線断面図、(ｂ)は、図１３に例示した通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【図１５】従来の更に別の通気ダクトを一部省略して例示した部分斜視図である。
【図１６】 (ａ)は、図１５のＺ−Ｚ線断面図、(ｂ)は、図１５に例示した通気ダクトの吹出口から吹出す調温空気の風速分布態様を示した説明図である。
【符号の説明】
１２ ダクト本体
１４ 第１壁部
１６ 第２壁部
２０ 吹出口
３２ 曲面壁部
３４ 平面壁部
３６ 折曲連接部分
３８ 上流側端縁(吹出口２０の)
Ｄ 幅寸法(ダクト本体１２の出口部分)
Ｅ 横寸法(吹出口２０の)
Ｌ 延長ライン(第２壁部１６の)
Ｐ１ 第１位置
Ｐ２ 第２位置
Ｐ３ 第３位置
Ｐ４ 第４位置
Ｒ 曲率半径(曲面壁部３２の)[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ventilation duct, and more specifically, includes a first wall portion and a second wall portion that form a duct wall facing each other, and an air outlet opened at an end of the first wall portion. In addition, the present invention relates to a ventilation duct that allows air or the like that has been introduced from the upstream side to pass through the air outlet while being diverted in a direction substantially perpendicular to the flow direction.
[0002]
[Prior art]
For example, in various vehicles such as passenger cars, passenger cabin air conditioning is performed by temperature-controlled air sent from an air conditioner unit mounted on the vehicle body. For this reason, an air outlet for blowing out the temperature-controlled air into the passenger compartment is disposed at a required position of a vehicle interior member such as an instrument panel or a roof panel. Are connected by a ventilation duct for circulating and guiding the temperature-controlled air.
[0003]
Here, the ventilation duct is disposed in a narrow space defined between the vehicle interior member and the vehicle body on the back side of the vehicle interior member, and thus has a narrow flat outer shape, Furthermore, there are many cases in which it is unavoidable to form a complex uneven outer surface shape. That is, the ventilation duct 10 is formed of, for example, a first wall portion 14 and a second wall portion 16 that form a duct wall of the duct body 12 so as to face each other, as schematically shown in FIG. An air inlet 18 connected to an air delivery unit (not shown) of the air conditioner unit or another ventilation duct is opened at one end of the air conditioner unit 16 and the other end of the first wall 14 is An air outlet 20 is opened from the required position of the vehicle interior member to the passenger compartment. As a result, the temperature-controlled air introduced from the upstream side inlet 18 is sequentially discharged from the outlet 20 after being moved through the duct body 12. In addition, the technique relevant to the said ventilation duct is disclosed by patent document 1 etc., for example.
[0004]
[Patent Document 1]
JP 2000-103223 A
[0005]
[Problems to be solved by the invention]
By the way, the ventilation duct 10 illustrated in FIG. 11 is, as shown in FIG. 12 (a), (1) the air outlet 20 opened in a horizontally long rectangular shape compared to the cross-sectional area of the duct body 12 having a flat shape. (2) The direction in which the temperature-controlled air is blown from the outlet 20 is a short direction substantially perpendicular to the flow direction (longitudinal direction) in the duct body 12. ing. Therefore, the temperature-controlled air introduced from the upstream inlet 18 is accelerated and moved appropriately in the duct body 12 having a small cross-sectional area, so that it will collide with the downstream wall of the duct adjacent to the outlet 20 at one end. Then, after this collision, it suddenly changes in a direction substantially orthogonal to move toward the outlet 20 (FIG. 12 (a)). Therefore, as shown in FIG. 12 (b), the temperature-controlled air discharged from the outlet 20 has a main flow in the left side region (downstream side region) of the outlet 20 as apparent from the wind speed distribution pattern of the outlet 20. ) In a narrow area, and hardly blows out from the right area (upstream area) of the outlet 20. That is, the appropriate wind speed region (for example, the shaded display portion in FIG. 12 (b)) W having a specified wind speed (for example, 12 m / s) is biased toward the left region of the outlet 20 and its area is considerably narrow. The performance was extremely low. Therefore, inconveniences such as (a) a region where the wind speed is locally increased are formed and blowing noise increases, and (b) efficient and comfortable air conditioning in the passenger compartment cannot be performed. It was.
[0006]
Therefore, in order to avoid the above-mentioned inconvenience, a back surface portion facing the opening region of the outlet 20 in the second wall portion 16 is formed as a curved surface portion 22 as shown in FIG. 13, for example, or as shown in FIG. Thus, a countermeasure has been taken to form the inclined surface portion 24 as a so-called diverted guide surface for temperature-controlled air. However, in the ventilation duct 10 illustrated in FIG. 13, there is a slight difference depending on the setting of the curvature radius of the curved surface portion 22, but as shown in FIGS. 14A and 14B, the ventilation in FIG. Compared with the duct 10, the improvement of the air distribution performance is hardly achieved. On the other hand, in the ventilation duct 10 illustrated in FIG. 15, although there are some differences from the setting of the inclination angle and length of the inclined surface portion 24, as shown in FIGS. 16 (a) and 16 (b), Although a slight improvement in the air distribution performance can be confirmed as compared with the ventilation duct 10 of 11, the air distribution performance that is still satisfactory cannot be obtained.
[0007]
For this reason, even when an air outlet that allows the occupant to adjust the blowing direction is separately installed, a blowing diverting device, a rectifying network, etc. are prepared as separate members, and these are additionally arranged on the front side of the outlet 20. It was necessary to take measures to improve the air distribution performance by expanding the area and correcting the position of the appropriate wind speed region W that provides the specified wind speed. However, since the diverting device, the rectifying network, and the like are separately manufactured, there has been a problem that the manufacturing cost increases due to the additional addition of parts cost, labor cost, and the like.
[0008]
OBJECT OF THE INVENTION
The present invention has been proposed to suitably solve the above-described problems, and an object of the present invention is to provide a ventilation duct that improves the air distribution performance with respect to the air discharged from the air outlet.
[0009]
[Means for Solving the Problems]
In order to solve the above-mentioned problems and achieve the intended object, the present invention is established at the first wall portion and the second wall portion that form a duct wall facing each other, and at the end of the first wall portion. In the ventilation duct that has the air outlet, and the air or the like introduced from the upstream side is made to pass out from the air outlet while turning in a direction substantially orthogonal to the flow direction thereof,
A back wall portion facing the opening region of the air outlet in the second wall portion is curved from a curved wall portion extending from the second wall portion to the air outlet side, and from an edge of the curved wall portion. Formed with a flat wall extending along the air outlet,
The air or the like introduced from the upstream side is configured to be widely discharged from the outlet by changing the direction of the air in a dispersed state toward the outlet in the process of moving along the curved wall portion. It is characterized by.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Next, the ventilation duct according to the present invention will be described below with reference to the accompanying drawings by way of preferred embodiments. In addition, about the site | part and member, etc. which are the same as the conventional ventilation duct 10 illustrated in FIG.11, FIG.13, FIG.15 etc., the same code | symbol is attached | subjected and demonstrated.
[0011]
FIG. 1 is a schematic perspective view illustrating a ventilation duct according to a preferred embodiment of the present invention with a part thereof omitted, and FIG. 2 is a sectional view taken along line II-II in FIG. The ventilation duct 30 of the embodiment is formed of a first wall portion 14 and a second wall portion 16 that are opposed to each other to form a duct wall of the duct body 12, and are integrally molded based on, for example, a known blow molding technique. A hollow body made of synthetic resin (polyethylene). Then, at one end portion of the second wall portion 16, an inlet 18 connected to an air delivery portion of an air conditioner unit (not shown) or another ventilation duct is opened, and the other end of the first wall portion 14 is opened. An air outlet 20 is provided at the end of the vehicle so as to face the passenger compartment from a required position such as a vehicle interior member. That is, the right side of the drawing in FIG. 1 is the upstream side of the ventilation duct 30, and the left side of the drawing is the downstream side of the ventilation duct 30.
[0012]
Here, the inner surface dimension of the air circulation part in the ventilation duct 30 of the embodiment is set as follows. First, the vertical dimension G of each part from the upstream end to the downstream end is substantially the same in any part in the longitudinal direction, and is set to about 50 mm, for example. On the other hand, the width dimension of the air circulation portion is different for each part in the longitudinal direction, and the width dimension C of the duct body 12 as a main body is set to about 20 mm. That is, the duct body 12 is narrowest in the air circulation portion of the ventilation duct 30 and has a vertically long flat shape. In addition, the downstream end side of the duct main body 12 is appropriately formed in an expanded shape, and the width dimension D of the outlet portion facing the air outlet 20 is set to about 35 mm.
[0013]
On the other hand, the air outlet 20 opened in the first wall portion 14 has a horizontally long rectangular shape with a lateral dimension E = 100 mm and a longitudinal dimension F = 50 mm. Accordingly, the opening area of the outlet 20 is about three times the air circulation area at the outlet portion of the duct body 12 and about five times the air circulation area at the center portion of the duct body 12.
[0014]
In the ventilation duct 30 of the embodiment, the temperature-controlled air that has moved through the duct main body 12 and escaped from the outlet portion of the duct main body 12 is appropriately redirected toward the air outlet 20 and the air outlet 20. In order to blow out to a wide area, the following duct wall structure is adopted to improve the air distribution performance of the temperature-controlled air. That is, a curved wall 32 extending in a curved manner from the second wall 16 toward the outlet 20, and a curved surface of the rear surface facing the opening area of the outlet 20 in the second wall 16. A flat wall portion 34 extending from the edge of the wall portion 32 along the air outlet 20 is formed. Therefore, as is apparent from FIG. 2, the back surface portion of the second wall portion 16 facing the air outlet 20 includes a bent connection portion 36 that is a boundary portion between the curved wall portion 32 and the flat wall portion 34. The temperature-controlled air protrudes in the flow direction of the temperature-controlled air between the outlet portion of the duct body 12 and the air outlet 20, and thereby moves the temperature-controlled air that has escaped from the duct body 12 along the curved wall portion 32. In the process, the direction is changed in a dispersed state toward the air outlet 20, so that the air can be widely discharged from the air outlet 20.
[0015]
And in the ventilation duct 30 of the embodiment, the width dimension D = 35 mm at the outlet portion of the duct body 12, the lateral dimension E = 100 mm of the outlet 20, and the longitudinal dimension F = 50 mm of the outlet 20, It is required that the temperature-controlled air that has been introduced from the inlet 18 moves through the duct body 12 at a flow velocity of 14 m / s and then is widely blown from the outlet 20 at a specified wind speed of 12 m / s. Therefore, in order to improve the air distribution performance, the dimensions of the portions related to the curved wall portion 32 and the flat wall portion 34 are set as follows. The dimensions related to the curved wall portion 32 and the flat wall portion 34 are derived based on the experimental results conducted by the applicant of the present application, and the details of the experiments and the experimental results will be described in detail later. To do.
[0016]
First, the curved wall 32 extends in an arc shape having a radius of curvature R joined in a tangential direction with respect to the second wall 16, and the temperature-controlled air that has moved through the duct body 12 is blown into the blowing wall 12. It can be smoothly turned to the outlet 20 side. Here, when the width D at the outlet portion of the duct body 12 is set to 35 mm, the curvature radius R is optimally set in the range of 40 to 90 mm, preferably about 50 to 80 mm. That is, the curvature radius R of the curved wall portion 32 is set to about 1.2 to 2.5 times (1.2D to 2.5D) the width dimension D at the outlet portion of the duct body 12.
[0017]
The flat wall portion 34 is formed between the downstream end wall portion of the duct and the curved wall portion 32, and is separated from the extension line L of the second wall portion 16 toward the outlet 20 by a required amount. And extends in the same direction as the second wall portion 16 (a direction parallel to the extension line L). The flat wall portion 34 does not need to be formed so as to extend in the same direction as the second wall portion 16, for example, the downstream end wall portion side is displaced in the direction opposite to the outlet 20 from the curved wall portion 32 side. The inclined state or the inclined state in which the downstream end wall portion side is displaced from the curved wall portion 32 side to the outlet 20 side may be used.
[0018]
In addition, the setting position of the bent connection portion 36 between the curved wall portion 32 and the flat wall portion 34 is the formation position of the curved wall portion 32 in the longitudinal direction of the duct and the flat wall portion 34 in the short direction of the duct. It is determined by the relationship with the formation position. First, the setting position of the bent connecting portion 36 in the longitudinal direction of the duct is a first position P1 that is a required distance away from the upstream end edge 38 of the air outlet 20 to the downstream side, and further downstream from the first position P1. And a second position P2 that is a required distance away (FIG. 3). Specifically, when the lateral dimension E of the air outlet 20 is set to 100 mm, the interval S1 between the upstream edge 38 of the air outlet 20 and the first position P1 is about 30 mm, and the first position The distance S2 between P1 and the second position P2 is about 30 mm (the distance (S1 + S2) from the upstream edge 38 is 60 mm). In other words, the interval S1 between the upstream end edge 38 of the air outlet 20 and the first position P1 is about 0.3 times (0.3E) the lateral dimension E at the air outlet 20, and the first The interval S2 between the position P1 and the second position P2 is about 0.3 times (0.3E) the lateral dimension E at the outlet 20, and the set position of the bent connecting portion 36 in the longitudinal direction of the duct Is an appropriate position between the first position P1 and the second position P2. When the center line CL of the outlet 20 is taken as a reference, a first position P1 that is separated from the center line CL upstream by 0.2 times (0.2E) the lateral dimension E at the outlet 20; From the center line CL to the downstream side, it is between the second position P2 spaced 0.1 times (0.1E) the lateral dimension E at the outlet 20.
[0019]
Further, the setting position of the bent connecting portion 36 in the short direction of the duct is a third position P3 spaced from the extension line L of the second wall portion 16 to the outlet 20 side by a required distance, and the third position P3. It is set between the position P3 and the fourth position P4 further away from the outlet 20 by a required distance (FIG. 3). Specifically, when the width D at the exit portion of the duct body 12 is set to 35 mm, the distance H1 between the extension line L and the third position P3 is about 15 mm, and the third position P3 and the The distance H2 from the fourth position P4 is about 10 mm (the distance from the extension line L (H1 + H2) is 25 mm). In other words, the distance H1 between the extension line L and the third position P3 is set to about 0.4 times (0.4D) the width dimension D at the outlet portion of the duct body 12, and the third position P3 The interval H2 with respect to the fourth position P4 is about 0.3 times (0.3D) the width D at the outlet portion of the duct body 12, and the setting of the bent connecting portion 36 in the short direction of the duct is set. The position is appropriately set between the third position P3 and the fourth position P4. When the extension line L is taken as a reference, the distance (H1 + H2) between the extension line L and the fourth position P4 is 0.7 times (0.7D) the width D at the outlet portion of the duct body 12. ) It will be about.
[0020]
In the ventilation duct 30 of the embodiment formed as described above, the back surface portion facing the opening area of the air outlet 20 in the second wall portion 16 is curved from the second wall portion 16 to the air outlet 20 side. Formed by the curved wall portion 32 extending to the edge and the planar wall portion 34 extending from the end edge of the curved wall portion 32 along the outlet 20, thereby controlling the temperature-controlled air from the duct body 12. In the process of moving along the curved wall portion 32, the direction can be changed in a dispersed state toward the air outlet 20, so that the air can be widely discharged from the air outlet 20. And by setting the various dimensions related to the curved wall portion 32 and the flat wall portion 34 as described above, it is preferable to enlarge and position properly the appropriate wind speed region W of the temperature-controlled air blown out from the air outlet 20. It can be planned. And since the appropriate wind speed area | region W of temperature-controlled air expands, while the local change of the wind speed reduces and a blowing noise reduces, efficient and comfortable air conditioning in a passenger | crew interior can be implemented. Furthermore, when improving the air distribution performance, it is not necessary to prepare a separate member such as a blowing diverter or a rectifying network, except when an air outlet that allows the occupant to adjust the blowing direction is separately installed. Since it can be integrally formed by a molding technique or the like, the cost does not increase.
[0021]
Next, in the ventilation duct 30 of the embodiment, the basis for setting various dimensions related to the curved wall portion 32 and the flat wall portion 34 will be described based on the contents of experiments and the results of experiments conducted by the applicant of the present application. As described above, the air distribution performance of the temperature-controlled air in the ventilation duct 30 affects (1) the formation position of the curved wall portion 32 in the longitudinal direction of the duct, and (2) the plane in the short direction of the duct. The formation position of the wall 34, (3) the radius of curvature R of the curved wall 32, and the like. Therefore, Experiment 1 for determining the radius of curvature R and the formation position of the curved wall portion 32 and Experiment 2 for determining the formation position of the planar wall portion 34 were performed.
[0022]
Experiment 1 is a curved surface with the formation position of the flat wall portion 34 in the short direction of the duct being constant (the distance H from the extension line L of the second wall portion 16 is 20 mm). In each of the three types of ventilation ducts 30A, 30B, and 30C in which the curvature radius R of the wall portion 32 is set to 20 mm, 50 mm, and 80 mm, four types in which the formation position of the curved wall portion 32 in the longitudinal direction of the duct is changed. The wind distribution performance was tested. That is, the first ventilation duct 30A (FIG. 5A) in which the curvature radius R of the curved wall portion 32 is 20 mm (FIG. 5A), and the second ventilation duct 30B in which the curvature radius R of the curved wall portion 32 is 50 mm (FIG. 5B). ), In the third ventilation duct 30C (FIG. 5C) in which the radius of curvature R of the curved wall portion 32 is 80 mm (FIG. 5C), by changing the formation position of the curved wall portion 32 in the longitudinal direction of the duct, (1) a first setting position where the setting position of the bent connecting portion 36 in the longitudinal direction is a distance Sa (30 mm) from the upstream edge 38 of the outlet 20; (2) from the upstream edge 38; Second set position with spacing Sb (50 mm) (matches the center line CL of the outlet 20), (3) Third set position with spacing Sc (70 mm) from the upstream edge 38, (4) Upstream side 4 types in total, 4th set position with spacing Sd (90mm) from edge 38 Experiments on wind distribution performance were conducted.
[0023]
Here, as points to consider in the evaluation of wind distribution performance,
(1) The area of the appropriate wind speed region W blown out at the specified wind speed in the temperature-controlled air blown from the outlet 20
(2) The position of the appropriate wind speed region W that is blown out at the specified wind speed in the temperature-controlled air blown from the outlet 20
(3) Pressure loss value,
It is necessary to consider these various data comprehensively. However, when the area and / or position of the appropriate wind speed region W is an important point for evaluation, the above points (1) and (2) should be taken into consideration, and when the pressure loss value is an important point, the above point (1) It is necessary to consider all of ▼, ▲ 2 ▼, ▲ 3 ▼.
[0024]
As shown in FIG. 4 (a), the evaluation method (1) is based on the distribution pattern of the temperature-controlled air at the outlet 20, and the opening area of the outlet 20 (lateral dimension E × vertical dimension). F) = A, and an appropriate wind speed region (shaded portion in the figure) W of the temperature-controlled air = B = area B / A is calculated and calculated. For example, when the temperature-controlled air is blown out from the entire area of the air outlet 20 at an appropriate wind speed, since B / A = 1, this is evaluated as 10 points (full score). When temperature-controlled air is blown out from approximately half at an appropriate wind speed, B / A = 0.5, and this is evaluated as 5 points.
[0025]
In the evaluation method (2), as shown in FIG. 4B, the center of the appropriate air velocity region W of the temperature-controlled air is displaced to the right or left with respect to the center line CL of the air outlet 20. It is carried out by determining whether it is doing. For example, when the appropriate wind speed region W coincides with the center line CL of the air outlet 20, it is evaluated as 5 points, and the point is decremented as the amount of deviation to the left or right side of the appropriate wind speed region W increases. When W is located at the left end or the right end of the outlet 20, it is evaluated as one point. In the case of the illustrated example based on this assumption, the center of the appropriate wind speed region W is slightly deviated to the left of the center line CL of the air outlet 20 and is substantially coincident with the four lines, so it is evaluated as four points. The
[0026]
Further, the pressure loss value of (3) is evaluated as shown in Table 1 in view of the fact that the conventional ventilation ducts 10 shown in FIGS. 11 to 16 are 116 to 119 (Pa) (see Table 2). A standard was set. That is, when a better result is obtained than each conventional ventilation duct 10 (when the pressure loss value is low), it is 5 points, and when it is the same level, it is 4 points, and when it is worse than this (pressure loss value is If it becomes higher), it is evaluated as 3 points, 2 points, 1 point according to the value.
[0027]
[Table 1]

[0028]
FIGS. 6 to 8 illustrate the experimental results in Experiment 1, and show the wind speed distribution mode of the temperature-controlled air at the outlet 20 under the above-described setting conditions. That is, FIG. 6 shows the wind speed distribution mode of each outlet 20 in the four types of the first ventilation duct 30A (FIG. 5A) in which the curvature radius R of the curved wall portion 32 is 20 mm, and FIG. FIG. 8 shows a wind speed distribution mode of each outlet 20 in the four types of the second ventilation duct 30B (FIG. 5B) in which the curvature radius R of the curved wall portion 32 is 50 mm, and FIG. The wind velocity distribution mode of each outlet 20 in the four types of the third ventilation duct 30C (FIG. 5 (c)) with a curvature radius R = 80 mm is shown.
[0029]
Table 2 is a list showing four types of evaluation results in the first to third ventilation ducts 30A, 30B, and 30C based on the experimental results of Experiment 1 illustrated in FIGS. 5 and 6 to 8. It is. In the lower part of Table 2, the cases where the conventional three types of ventilation ducts 10 illustrated in FIGS. 11 to 16 are evaluated by the evaluation methods (1) to (3) are also shown. That is, in the conventional ventilation duct 10 shown in FIG. 11 and FIG. 12, the total evaluation obtained by summing up the evaluations (1) to (3) is 7.5 points. Similarly, the conventional ventilation duct 10 shown in FIG. 13 and FIG. In the other ventilation duct 10, the overall evaluation was 7.5, and in the other conventional ventilation duct 10 shown in FIGS. 15 and 16, the overall evaluation was 8.5.
[0030]
[Table 2]

[0031]
In the experiment 1, four types are used in the first ventilation duct 30A in which the curvature radius R of the curved wall 32 is set to 20 mm, and four types are used in the second ventilation duct 30B in which the curvature radius R of the curved wall 32 is set to 50 mm. Experiments were made on the air distribution performance of 12 types of ventilation ducts in total, with four types in the third ventilation duct 30C set to have a radius of curvature R of the wall portion 32 = 80 mm. The overall evaluation of each of these 12 types of ventilation ducts 30 is in the range of 8.5 (minimum) to 13.0 (maximum), and each of the conventional ventilation ducts shown in FIGS. A comprehensive evaluation equal to or better than that of the ventilation duct 10 was obtained, and most of them were better than the conventional ventilation ducts 10. In other words, a curved wall 32 extending from the second wall 16 to the side of the air outlet 20 in a curved manner at a back surface portion facing the opening area of the air outlet 20 in the second wall 16, The ventilation duct 30 of the embodiment formed by the flat wall portion 34 extending from the end edge of the curved wall portion 32 along the air outlet 20 is almost related to the positions where the curved wall portion 32 and the flat wall portion 34 are formed. Therefore, it can be evaluated that the air distribution performance is improved at least as compared with the conventional ventilation ducts 10 shown in FIGS.
[0032]
Regarding the area ratio B / A between the air outlet 20 and the appropriate air speed region W of the temperature-controlled air, as is clear from Table 2, in 12 types of ventilation ducts, better results than before were obtained. . As a tendency common to all of the first to third ventilation ducts 30A, 30B, and 30C, the curved wall portion 32 is adjusted to the upstream side (first formation position) of the duct. The appropriate air velocity region W of warm air can be enlarged, and more favorable results were obtained with the second ventilation duct 30B and the third ventilation duct 30C than with the first ventilation duct 30A. From this, when attempting to enlarge the appropriate wind speed region W of the temperature-controlled air, good results were obtained when the curvature radius R of the curved wall portion 32 was set to 50 mm or 80 mm. It is appropriate that the radius of curvature R is about 40 to 90 mm.
[0033]
As is apparent from Table 2, the position of the appropriate air speed region W of the temperature-controlled air with respect to the air outlet 20 has a curved surface as a tendency common to all of the first to third ventilation ducts 30A, 30B, 30C. When the formation position of the wall portion 32 is the first formation position, the appropriate wind speed region W is the center or substantially the center of the air outlet 20. However, when the setting position of the bent connecting portion 36 is set to the third forming position or the fourth forming position, the appropriate wind speed region W is biased to the left side or the left end of the air outlet 20. Therefore, when the position of the appropriate air velocity region W of the temperature-controlled air is desired to be the center or substantially the center of the outlet 20, the setting position of the bent connection portion 36 in the longitudinal direction of the duct is set to the upstream side of the outlet 20. It is appropriate to be between a position 30 mm away from the end edge 38 (first position P1) and a position 60 mm away from the upstream end edge 38 of the outlet 20 (second position P2).
[0034]
As is apparent from Table 2, the pressure loss value has a tendency to be common to all of the first to third ventilation ducts 30A, 30B, 30C, and the formation position of the curved wall portion 32 is defined as the first formation position. In contrast, the tendency to become the smallest when the formation position of the curved wall portion 32 is set to the fourth formation position is conspicuous. Therefore, when considering the reduction of the pressure loss value, it is desirable to set the setting position of the bent connecting portion 36 in the longitudinal direction of the duct as close as possible to the second position P2.
[0035]
In addition, in the comprehensive evaluation obtained by adding and totaling the evaluations (1) to (3), the following setting conditions were 10 points or more. First, in the case of the 1st ventilation duct 30A set to the curvature radius R = 20mm of the curved wall part 32, the comprehensive evaluation did not become 10 points or more. Further, in the case of the second ventilation duct 30B where the curvature radius R of the curved wall portion 32 is set to 50 mm, when the formation position of the curved wall portion 32 is set to the first formation position or the second formation position, the comprehensive evaluation is performed. The scores were 13 and 12 respectively. Further, in the case of the third ventilation duct 30C where the curvature radius R of the curved wall portion 32 is set to 80 mm, the overall evaluation is performed when the formation position of the curved wall portion 32 is set as the first formation position and the second formation position. They were 12 and 11 points, respectively.
[0036]
Therefore, from the result of Experiment 1, the curvature radius R of the curved wall portion 32 is appropriately about 40 to 90 mm as described above, so that the width dimension D (35 mm) of the outlet portion of the duct body 12 is 1. It can be concluded that it is desirable to set to about 2 to 2.5 times (1.2D to 2.5D).
[0037]
In addition, the setting position of the bent connecting portion 36 in the longitudinal direction of the duct is the first position P1 30 mm away from the upstream end edge 38 of the air outlet 20 to the downstream side, and the first position P1 to the downstream side. It is desirable that the distance between the second position P2 and the second position P2 is 30 mm apart (separated 60 mm downstream from the upstream edge 38 of the air outlet 20). In other words, the set position of the bent connecting portion 36 in the longitudinal direction of the duct is 0.3 times (0.3E) the lateral dimension E of the air outlet 20 from the upstream edge 38 of the air outlet 20 to the downstream side. ) And a first position P1 separated by a distance corresponding to 0.3 times (0.3E) the lateral dimension E of the outlet 20 from the first position P1 to the downstream side. It can be concluded that it is desirable to be between the two positions P2.
[0038]
In Experiment 2, the curved wall portion 32 has a constant radius of curvature R and the curved wall portion 32 is formed at a constant position, and the formation position of the flat wall portion 34 in the short direction of the duct is changed. The wind distribution performance was tested for each of the four types. That is, the curvature radius R of the curved wall portion 32 is set to 80 mm, the setting position of the bent connecting portion 36 in the longitudinal direction of the duct is set to the interval S from the upstream end edge 38 of the outlet 20 by 30 mm (the first formation). 9), as shown in FIG. 9, the setting position of the bent connecting portion 36 in the short direction of the duct is set to (1) the distance Ha (10 mm) from the extension line L of the second wall portion 16. (5) the sixth formation position, (2) the sixth formation position, which is the distance Hb (15 mm) from the extension line L, (3) the seventh set position, which is the distance Hc (20 mm) from the extension line L, (4) Experiments on the air distribution performance were performed on a total of four types, that is, the eighth set position with a distance Hd (25 mm) from the extension line L. Therefore, the seventh formation position (interval Hc = 20 mm) is included in Experiment 1.
[0039]
FIG. 10 illustrates experimental results in Experiment 2, and shows the wind speed distribution mode of the outlet 20 in the four types described above. Table 3 is a list showing the four types of evaluation results by the evaluation methods (1) to (3) based on the experimental results illustrated in FIG.
[0040]
[Table 3]

[0041]
In the experiment 2, an experiment was conducted on the air distribution performance in a total of four types of ventilation ducts 30 in which the formation position of the flat wall portion 34 is different. The overall evaluation of each of these four types of ventilation ducts 30 is in the range of 9.5 (minimum) to 13.0 (maximum). Overall evaluation better than each ventilation duct 10 was obtained. In other words, a curved wall 32 extending from the second wall 16 to the side of the air outlet 20 in a curved manner at a back surface portion facing the opening area of the air outlet 20 in the second wall 16, As described above, the ventilation duct 30 of the embodiment formed by the flat wall portion 34 extending from the end edge of the curved wall portion 32 along the air outlet 20 includes the curved wall portion 32 and the flat wall portion 34. Regardless of the formation position, it can be evaluated that the air distribution performance is improved at least as compared with the conventional ventilation ducts 10 shown in FIGS.
[0042]
Then, as the setting position of the bent connecting portion 36 in the short direction of the duct is brought closer to the outlet 20 side (as the distance H from the extension line L is increased), the area of the outlet 20 is adjusted. The area ratio B / A with the area of the appropriate air velocity region W of warm air becomes good (evaluation (1)), and the position of the appropriate air velocity region W of temperature-controlled air at the outlet 20 becomes good (evaluation (2)). ). However, conversely, the pressure loss value tends to increase as the set position of the bent connecting portion 36 in the short direction of the duct is brought closer to the outlet 20 (evaluation (3)). From this, the setting position of the bent connecting portion 36 in the short direction of the duct is the third position P3 spaced 15 mm from the extension line L of the second wall portion 16 to the outlet 20 side, and this It is desirable to be between the third position P3 and the fourth position P4 which is further 15 mm away from the outlet 20 side.
[0043]
In other words, the setting position of the bent connecting portion 36 in the short direction of the duct is the width D at the outlet portion of the duct body 12 from the extension line L of the second wall portion 16 to the outlet 20 side. A third position P3 that is separated by a distance corresponding to about 0.4 times (0.4D), and a width dimension D at the outlet portion of the duct body 12 from the third position P3 to the outlet 20 side. It can be concluded that it is desirable to be between the fourth position P4 separated by a distance corresponding to about 0.3 times (0.3D).
[0044]
In addition, the ventilation duct of this application is not limited to what is arrange | positioned at the back side of a vehicle interior member, but is various ducts implemented in order to blow out after guiding various gas, such as air, in various fields. It can be implemented as.
[0045]
【The invention's effect】
As described above, according to the ventilation duct according to the present invention, the back surface portion facing the opening region of the outlet in the second wall portion is curvedly extended from the second wall portion to the side of the outlet. By forming the wall portion and the flat wall portion extending from the edge of the curved wall portion along the air outlet, air or the like introduced from the upstream side moves along the curved wall portion. In the process, the direction can be changed in a dispersed state toward the air outlet, and thus the air can be widely discharged from the air outlet. And, by setting the dimensions related to the curved wall portion and the flat wall portion as described above, there is an advantage that the appropriate wind speed region such as the air blown out from the outlet can be appropriately enlarged and the position can be appropriately optimized. is there.
In addition, since the appropriate wind speed region of the temperature-controlled air is expanded, the local change in the wind speed is reduced to reduce the blowing noise, and the passenger compartment can be efficiently and comfortably air-conditioned. Furthermore, when improving the air distribution performance, it is not necessary to prepare a separate member such as a blowing diverter or a rectifying network, except when an air outlet that allows the occupant to adjust the blowing direction is separately installed. Since it can be integrally formed by a molding technique or the like, it has extremely beneficial effects such as no increase in manufacturing cost.
[Brief description of the drawings]
FIG. 1 is a schematic perspective view illustrating a ventilation duct according to a preferred embodiment of the present invention with a part omitted.
2 is a cross-sectional view taken along line II-II in FIG.
FIG. 3 is an explanatory diagram showing a set position in the longitudinal direction of the duct and a set position in the short direction of the duct with respect to the bent connection portion between the curved wall portion and the flat wall portion.
4A is an explanatory diagram showing a method for evaluating the area ratio between the opening area of the air outlet and the area of the appropriate wind speed region of the temperature-controlled air, and FIG. 4B is a temperature control for the air outlet. It is explanatory drawing which showed the method of evaluating the position of the appropriate wind speed area | region of air.
FIG. 5A is an explanatory sectional view illustrating four types of forms in which the formation position of the curved wall portion is changed with respect to the first ventilation duct set to a curvature radius R = 20 mm of the curved wall portion; ) Is an explanatory cross-sectional view illustrating four types of configurations in which the curved wall portion is changed in the formation position with respect to the second ventilation duct set to a curvature radius R = 50 mm of the curved wall portion, and (c) is a curved wall portion. It is explanatory sectional drawing which illustrated the 4 types form which changed the formation position of this curved-surface wall part regarding the 2nd ventilation duct set to the curvature radius R = 80mm.
6 is an explanatory view showing a wind speed distribution mode of temperature-controlled air blown out from the outlet of each of the four types of first ventilation ducts shown in FIG. 5 (a).
7 is an explanatory view showing a wind speed distribution mode of temperature-controlled air blown out from the outlet of each of the four types of second ventilation ducts shown in FIG. 5 (b).
FIG. 8 is an explanatory diagram showing a wind speed distribution mode of temperature-controlled air blown out from the outlet of each of the four types of third ventilation ducts shown in FIG. 5 (c).
FIG. 9 is an explanatory sectional view illustrating the form of four types of ventilation ducts in which the formation position of the flat wall portion is changed.
10 is an explanatory diagram showing a wind speed distribution mode of the temperature-controlled air blown out from the outlet of each of the four types of ventilation ducts shown in FIG. 9. FIG.
FIG. 11 is a partial perspective view illustrating a conventional ventilation duct with a part thereof omitted.
12A is a cross-sectional view taken along the line XX of FIG. 11, and FIG. 12B is an explanatory diagram showing a wind speed distribution mode of the temperature-controlled air blown out from the air outlet of the ventilation duct illustrated in FIG. is there.
FIG. 13 is a partial perspective view illustrating another conventional ventilation duct with a part omitted.
14A is a cross-sectional view taken along the line YY of FIG. 13, and FIG. 14B is an explanatory diagram showing a wind speed distribution mode of the temperature-controlled air blown out from the air outlet of the ventilation duct illustrated in FIG. is there.
FIG. 15 is a partial perspective view illustrating another conventional ventilation duct with a part omitted.
16A is a cross-sectional view taken along the line ZZ in FIG. 15, and FIG. 16B is an explanatory diagram showing a wind speed distribution mode of the temperature-controlled air blown out from the air outlet of the ventilation duct illustrated in FIG. is there.
[Explanation of symbols]
12 Duct body
14 First wall
16 Second wall
20 outlet
32 Curved wall
34 Plane wall
36 bent joints
38 upstream edge (of outlet 20)
D width dimension (exit part of duct body 12)
E Horizontal dimension (of outlet 20)
L extension line (for second wall 16)
P1 1st position
P2 2nd position
P3 3rd position
P4 4th position
R radius of curvature (of curved wall 32)

Claims (9)

A first wall portion (14) and a second wall portion (16) forming a duct wall facing each other, and a blower outlet (20) opened at an end of the first wall portion (14) In the ventilation duct that is made to pass out from the air outlet (20) while turning the air or the like introduced from the upstream side in a direction substantially orthogonal to the flow direction thereof,
A curved wall extending in a curved manner from the second wall portion (16) to the side of the air outlet (20) at a back surface portion facing the opening region of the air outlet (20) in the second wall portion (16). A portion (32) and a planar wall portion (34) extending from the edge of the curved wall portion (32) along the air outlet (20),
From the air outlet (20), the air or the like introduced from the upstream side is changed in a dispersed state toward the air outlet (20) in the process of moving along the curved wall portion (32). A ventilation duct characterized by being configured to allow wide passage. The bent joint portion (36) between the curved wall portion (32) and the flat wall portion (34) is a duct body (12) formed by the first wall portion (14) and the second wall portion (16). Projecting in the flow direction of the air or the like between the outlet portion of the air outlet and the air outlet (20), whereby the air or the like from the duct body (12) can be diverted toward the air outlet (20). The ventilation duct according to claim 1. The curved wall portion (32) extends in an arc shape, and its radius of curvature (R) is about 1.2 to 2.5 times the width dimension (D) at the outlet portion of the duct body (12). The ventilation duct according to claim 1 or 2, which is set. The set position of the bent connecting portion (36) in the longitudinal direction of the duct is the first position (P1) spaced from the upstream end edge (38) of the outlet (20) by a required distance to the downstream side, and the first position (P1). The ventilation duct according to claim 2 or 3, wherein the ventilation duct is between a first position (P1) and a second position (P2) that is further away from the downstream by a required distance. The distance between the upstream edge (38) and the first position (P1) is about 0.3 times the lateral dimension (E) of the air outlet (20) provided in a rectangular shape. 4. The ventilation duct according to 4. The distance between the first position (P1) and the second position (P2) is about 0.3 times the lateral dimension (E) of the air outlet (20) provided in a rectangular shape. Or the ventilation duct of 5. The setting position of the bent connecting portion (36) in the short direction of the duct is a third position separated from the extension line (L) of the second wall portion (16) toward the outlet (20) by a required distance. The point between (P3) and the fourth position (P4) that is further away from the third position (P3) toward the outlet (20) by a required distance. Ventilation duct. The ventilation duct according to claim 7, wherein a distance between the extension line (L) and the third position (P3) is about 0.4 times a width dimension (D) at an outlet portion of the duct body (12). . The distance between the third position (P3) and the fourth position (P4) is about 0.3 times the width dimension (D) at the outlet portion of the duct body (12). Ventilation ducts.

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