M296961 ύ 八、新型說明: 【新型所屬之技術領域】 本創作係關於一種瓦斯爐燃燒器,尤其係關於一種瓦斯 爐燃燒器,其具有新穎之瓦斯氣流通道,可促進瓦斯氣流移 動且在燃燒之前加速,以達成更有効率之燃燒,從而產生更 多的熱,並且具有熱及冷空氣(氧氣源)保存之設置,其可使 燃燒更完全,消耗更少的瓦斯氣,減少燃燒時產生煤煙及污 染物。 b 【先前技術】 高壓瓦斯爐燃燒器通常具有類似習用管路之內部瓦斯 ' 管形狀。該瓦斯管與缸體相連接,而該缸體具有甜甜圈形 狀、平坦表面、及位在該缸體中央處之空心缸體型部。當該 瓦斯流經過瓦斯管及缸體且隨後圍繞該缸體型部時,其將因 爲在瓦斯管中損失速率,撞擊位在該缸體中之該缸體型部、 及失去該速率之垂直部分,以致失去了大量的速率。此外, 該瓦斯流沿著被覆蓋以蓋盤之該缸體的平坦表面而流動;而 I 該蓋盤之形狀自俯視圖觀之係類似一甜甜圈。在該蓋盤上設 有一組孔,瓦斯可經此組孔而向上擴散出以供燃燒。因此, 該蓋盤之內部平坦表面將使得從所有部件處流過之瓦斯流 在到達該等孔之前,因爲撞擊該蓋盤之內表面而先損失了動 力與速率。此外,在瓦斯流流經該瓦斯管、缸體及蓋盤且在 其向上擴散至瓦斯孔前,其將先被反射並損失大量之速率。 這因而產生了較少於平常之熱功率。具有密集實心翼件且經 覆蓋之瓦斯爐燃燒器的架體將使得冷空氣無法充分地進 M296961 我 * 入,而此將在燃燒期間產生煤煙。 因此,本發明之第1目的在提供一種瓦斯爐燃燒器,其 具有改良之合乎空氣動力學原理之內部瓦斯氣通道結構,以 減少瓦斯氣流阻力,因此可以較小的瓦斯消耗量產生更多的 熱。 本發明之第2目的在提供一種瓦斯爐燃燒器,其中瓦斯 爐架體被設計成可藉著改變該缸體與蓋盤中之瓦斯流的方 向及調整其速率,而強迫該瓦斯流從該等瓦斯孔以較高之速 > 率流出,以便可產生最大之熱功率、消耗較少之瓦斯、及減 '少因不完全燃燒所產生之煤煙,因而發展出該瓦斯爐架體 ~ 【新型內容】 本創作之上述目的可由本創作所提供的一種瓦斯爐燃 燒器來達成,其中沿著內部瓦斯管之突脊與缸體可用以形成 一陣瓦斯流。在該缸體中似碗狀之弧形且不相稱的型部以及 在前部處傾斜並彎折至後部的彎脊圍繞來自該瓦斯管處之 瓦斯流,使該缸體中之瓦斯流改變方向並直接加速流至瓦斯 t 孔。位在該缸體中心處之該等密集且實心的突脊有助於維持 且加熱該內架體。在內與外瓦斯孔之間擁有各自大及小突脊 之該蓋盤的內側可加速該瓦斯流並減小該反射力。位於該瓦 斯爐架體的諸翼件上之較適化空隙大小或孔可讓冷空氣自 外部進入以達到更佳之燃燒。 【實施方式】 第1圖顯示習知之瓦斯爐燃燒器,其包括下列之主要裝 置:閥(1)、文氏管開口( 2 )、及被用以依據需求而調節空 M296961 i 1 . 氣之空氣調節板(3 )。藉此,瓦斯將可流經瓦斯管(4 )而 進入缸體(5)及蓋盤(6),並向上擴散至內瓦斯孔(?)及 外瓦斯孔(8 )以便進行燃燒。瓦斯爐架體(9 )可用以防風 及保持熱。某些類型之瓦斯爐可依據設計及使用目的而擁有 一個以上之前述裝置,例如兩個閥、兩個或更多之瓦斯管、 多個缸體型部、或複數個瓦斯孔等。 第2圖係顯示根據本創作所實施之瓦斯爐燃燒器的諸裝 置’其類似於習用瓦斯爐燃燒器的諸裝置,但不同處係在於 包括內表面及一些外部元件,其可在瓦斯流經過該瓦斯管 (10)、缸體(11)、蓋盤(12)並向上擴散至該等內瓦斯孔 (1 J )及外瓦斯孔(1 4 )時協助調節該瓦斯流之速率並改變 其方向。結果,該瓦斯流可在該等瓦斯孔之周圍顯著地加 速。此外,在該瓦斯爐架體(1 5 )上形成複數個孔(7 0 )時, 將可使外側之空氣得進入以達成更完全之燃燒。 第3圖係習知缸體之一部分剖面圖,其顯示該瓦斯流在 該瓦斯管(4 )及缸體(5 )中之運動。當該習知瓦斯爐燃燒 器之瓦斯流(1 6 )自該閥或噴嘴(1 )處流出時,其將在到 達該已裝設了缸體型部(1 7 )之缸體(5 )前,先行經過該 瓦-斯管(4 )。此一部分之瓦斯流將撞擊該缸體中之缸體型 部(1 7 )。因此,該瓦斯流(1 6 )將損失某種程度之速率。 第4、5、6及1 0圖顯示根據本創作所實施之缸體,其 中該內部瓦斯管(1 〇 )被設計成可沿著該被連接至文氏管開 口(2)處之瓦斯管的下表面(18)及上表面(19)而具有 該等突脊。該等下突脊(18)具有各自之大及小尺寸,並將 M296961 4 % 突脊(76)升局至該缸體之缸體型部(η)之高度處爲止, 而該缸體型部係用以擴大該瓦斯管之內表面,以便可增加流 動速率並形成一陣從該文氏管開口流動至該瓦斯管之瓦斯 流(20 )。該等被升高之突脊用以將瓦斯流(2〇 )分成兩路 (21 ) ( 22 ),藉以避免撞擊該缸體中之缸體型部(23 )。由 瓦斯管所流出之某程度的瓦斯流將沿該等突脊()而流 動。因此,瓦斯流(24 )在該瓦斯管相同側(25 )將升高至 該缸體開口之高度處。 第4、5及11圖顯示該瓦斯管(1〇)之內表面上的該等 上突脊(19)’其係在到達該缸體(25)前先藉由分離成兩 路(2 6 )( 2 7 )而可於瓦斯管(丨〇 )之上側中分離並形成該 陣瓦斯流(2 0 )。此一部分之瓦斯流將於下文中提及。 第4、5及6圖顯示該瓦斯流(2 1 )( 2 2 )流經該瓦斯管 (1 〇 )後之運動。此一部分之瓦斯流在該瓦斯管相同側(2 5 ) 將升高至該缸體開口的高度處,其係由被固定於該缸體(i i ) 底板兩側之彎脊所支撐,且將用以圍繞該瓦斯流(2 1 ) ( 2 2 ) 之流向。這些彎脊之特徵在於:其在前側處被向上彎曲且略 彎折於該缸體中間部分(29 )上,並在該瓦斯管之相對側(33 ) 將弧形坡面(30)升高至該缸體之高度處。該彎曲表面(37) 之此一特徵可用以強迫該已被分成兩路之瓦斯流(2 1 )( 2 2 ) 改變方向並升高至該缸體開口( 2 5 )之高度,且因該瓦斯流 流過位在前側處之向上彎曲部分而顯著地加速。同時,該瓦 斯流之其餘部分環繞該缸體中之缸體型部(23 )及該等弧形 坡面(29 ) ( 3 0 )。該瓦斯流(3 1 ) ( 3 2 )因而顯著地變得更 M296961 I fc 快,此乃因爲此瓦斯流在該瓦斯管相對側(3 3 ) 上彎曲部分所致。 第3圖係顯示習知缸體之內側,其中該平坦 瓦斯管相同側及其相對側之對等部分(3 5 ): (3 6 ),其從俯視圖中觀看係呈一甜甜圈之形狀 繞該缸體中之缸體型部(1 7 )的瓦斯流(1 6 )將 之速率,此乃因爲在沿著該平坦底板流動之同 (16)係平行於該底板移動且並無將其本身升至 Φ 之高度處。 第7及8圖係顯示根據本創作所實施之該缸 — 其中該內壁係圓形且被彎曲似一碗形(3 4 )。其 小該瓦斯流(2 1 ) ( 2 2 ) ( 3 1 ) ( 3 2 )之變動及增加 以使該瓦斯流不致損失太大程度之速率,並可升 之整個開口的高度處。該缸體之內部形狀略較狹 斯管相對側(3 3 )將升高至該缸體開口之高度處 4及5圖所示,其用以在該瓦斯流(3 1 )( 3 2 )於 ® 中間部分(3 8 )及相對側(3 3 )處升高至該缸體 之前先行增加該瓦斯流(3 1 )( 3 2 )之速率。 第9、1 0、1 1圖顯示根據本創作所實施之該 斯流之運動。該移動至右側之瓦斯流(3 1 )更羅 此乃因爲該缸體之內側變得略較狹窄,並在該瓦 (33)升高至該缸體開口之高度處,一直到該等 斯流之突脊(3 9 )被連接至位在該瓦斯管相對側 該缸體開口周圍的該缸體表面爲止。這些突脊( 處流過該向 底板具有該 及相稱部分 。此外,圍 損失某程度 時,瓦斯流 該缸體開口 :體的內側, 亦可用以減 丨其上升力, 高至該缸體 窄並在該瓦 爲止,如第 該瓦斯管之 開口的高度 內側及該瓦 i著地加速, 斯管相對側 用以分離瓦 (33 )處之 3 9 )自俯視 -10- M296961 1 * , Η觀看係似一楔,而自一剖面例觀看則似弧形坡面。該等突 脊將該尖銳邊緣(4 0 )轉向該瓦斯流(3 1 )之方向。該尖銳 端(4 0 )之位置係幾近在該缸體之中間開口( 3 8 )周圍。該 等突脊(3 9 )被打造形成兩個溝槽(4 4 ),在此處該瓦斯流 (3 1 )分離成三路。該瓦斯流(3 1 )之第一部分會升高至該 等突脊(3 9 )之彎曲部分上方,並變成爲該移動至瓦斯管之 開□ ( 3 3 )處的瓦斯流(4 1 )。該瓦斯流(3 1 )之其餘部分 被強迫分離成兩路(42 )( 43 ),直接流至位在該瓦斯管之開 I 口( 3 3 )周圍之該等內瓦斯孔(丨3 )及外瓦斯孔(;1 4 ),並 因爲該瓦斯流被壓縮且變得略較狹窄而顯著地加速。沿該兩 ‘ 溝槽(44 )而在左側邊上移動之瓦斯流(3 2 )具有與該瓦斯 流(3 1 )相同之方向。請參圖9及1 1所示之該瓦斯流(73 ) (74)(75)的方向。 第1及3圖顯示該習知瓦斯爐燃燒器之缸體,其因爲在 中間處有一孔或空間(45 ),故自俯視圖中觀看時類似一甜 甜圈,而該孔或空間(45 )將會導致在燃燒時由該內瓦斯孔 7 )中的火陷所產生之熱的損失。因此,該瓦斯爐燃燒器 在該等孔或空間(45 )周圍處會損失某種程度之熱。 第1 0及2 0圖顯示根據本創作所實施之瓦斯爐燃燒器之 缸體,其被設計以藉由在該缸體中間處設置密集實心之孔 (47 )及弧形之坡面(48 )而貯存該內焰(46 )之熱,而該 等孔及弧形坡面可保持由該內焰(4 6 )所產生且旋轉於缸體 中心區域(49 )周圍之熱(50 ),所以該內焰提升熱部分(50 ) (熱之增加可藉由該等密集實心或不同高度之溝槽而達 -11- M296961 i * _ 成。該熱部分(5 Ο )因此可圍繞旋轉。)該缸體之中間 孔(5 1 )係用來固定繫結件(5 2 ),以便可將該缸體與 面相連接,藉此使該瓦斯爐燃燒器在操作期間不會移動 第12、13及14圖顯示該蓋盤,其內部尺寸(53) 稱且該內表面(5 6 )係平坦的。當該瓦斯流(5 7 )流經 體時,其將撞擊該內蓋盤(5 6 ),而該該內蓋盤(5 6 ) 平面係爲平坦的。因爲該瓦斯流在到達該等內瓦斯孔( 及外瓦斯孔(8 )前已先大部分地將本身反射了,故該 > 流(5 7 )之速率會減小。 第1 8及1 9圖顯示根據本創作所實施之該蓋盤之內 '其被不相稱地設計而構成其特徵。接近該瓦斯管之該蓋 內側(5 4 )具有標準之尺寸且在垂直與水平兩區段上變 較狹窄,一直到該瓦斯管之相對側(5 5 )爲止,而因爲 斯流被壓縮,故該等區段係用以強迫由該瓦斯管頂部所 之瓦斯流(2 6 )加速,一直到位在該瓦斯管相對側(5 5 之該蓋盤爲止。 > 第5、1 6及1 7圖顯示根據本創作所實施之該蓋盤 內表面被設計成爲具有特徵者。在達到瓦斯孔(1 3 )( 前之該等突脊(5 9 )( 6 0 )係用以減小在該蓋盤下方之 力並形成一陣之瓦斯流(6 1 ),其自該缸體流出並直接 該等內瓦斯孔(1 3 )及外瓦斯孔(1 4 )。該瓦斯流可在 該等內瓦斯孔(1 3 )及外瓦斯孔(1 4 )前加速,此乃因 係沿著彎折至該等瓦斯孔上方之該等突脊(5 9 )( 6 0 ) 面流動所致。由該等瓦斯孔擴散出之該瓦斯流(7 2 )則 的穿 該表 〇 係相 該缸 中之 :7) 瓦斯 側, 盤的 得略 該瓦 流出 )處 ,其 14 ) 反射 移向 到達 爲其 的表 係爲 M296961 ; ^ _ 所需要者。 第1 8及1 9圖顯示根據本創作所實施之該瓦斯爐燃燒器 的蓋盤之內側,其中該等突脊(5 9 )係圓形且呈彎曲狀。此 外’該等圓形之突脊(6 0 )被一起連接於該等內瓦斯孔(1 3 ) 及外瓦斯孔(1 4 )之間。該等彎曲且呈圓形之突脊係位在該 瓦斯管之相同側(5 4 )’且略彎折於上一直到該瓦斯管之相 對側(55)爲止。在這些突脊(59)(60)上具有相互疊置 之各自小及大的突脊(6 2 )。這些突脊(6 2 )將該小尺寸轉 ® 向該瓦斯管之相同側(54 )。此特徵係爲在該等內瓦斯孔(1 3 ) 及外瓦斯孔(1 4 )之周圍構成該等溝槽(6 3 )( 6 4 ),其視爲 ' 分別具有大與小尺寸之該瓦斯流的空間。這些空間係用以壓 縮由該瓦斯管頂部處所流出之瓦斯流(2 6 )( 2 7 ),此較佳如 第1 8圖所示。該瓦斯流係經由在該等內瓦斯孔(1 3 )及外 瓦斯孔(14 )周圍之該等溝槽(6 3 ) ( 64 )而流出,以便可 在向外廣泛擴散至該等瓦斯孔之前先行增加該瓦斯流(2 6 ) (27 )之速率,一直到該瓦斯管之相對側(55 )爲止。請參 €► 看第19圖中之瓦斯流(65)(66)的方向。該等突脊(59) (60 ) ( 62 )亦係用以增加該瓦斯流(2 1 ) ( 22 ) ( 24 ) ( 3 1 ) (32)(41)(42)(43)(73)(74)(75)之速率並減小其反 射力,而該瓦斯流在到達該等內瓦斯孔(1 3 )及外瓦斯孔(1 4 ) 之前將先自該缸體開口處流出。 第1 6圖說明當使用該瓦斯爐燃燒器時,使用者可將該 蓋盤適當地放置在該瓦斯爐燃燒器上。請參看標示(67 ) 其顯示該蓋盤被正確地定置在該蓋盤之背後處。 M296961 . 第1圖顯示習知瓦斯爐燃燒器之瓦斯爐架體(9 ),其具 有可用以在器皿放置在其上且燃燒開始時貯存熱之密集實 心翼件(6 8 )。因爲在此作業中並沒有空氣或氧進入,故該 燃燒並未完全地達成。此外,該熱並不完全,且在燃燒期間 會產生煤煙。 第2圖顯示根據本創作所實施之瓦斯爐架體(i 5 ),其 被設計成具有下列特徵:其翼件(6 9 )具有經配置之空隙尺 寸或適當組之孔(70 ),其用來使冷空氣(7 可自外部進 > 入以供達到更完全之燃燒,減少煤煙且防止食物污染。因 此’該瓦斯爐架體之翼件(69)不易斷裂。空氣流撞擊在該 '瓦斯爐架體之翼件(69 )上的力可經由這些孔(70 )而消除。 雖然本創作在此係以較佳實施例參考圖面而詳細地說 明,但是上述說明僅供說明用途,並不限制本發明。在不違 離本創作之精神及範圍之下可作任何修改及變更,該範圍係 由申請專利範圍加以規範。 本創作之產業利用性 k 瓦斯係一種價格變得越來越高。因爲本創作之瓦斯爐燃 燒器可達成更有效的燃燒,若可被廣泛地應用於家庭、餐 廳、政府機構、飯店、工業界之時,可節省巨大之能源,且 減少環境污染。 【圖式簡單說明】 第1圖係習知瓦斯爐燃燒器之立體圖; 第2圖係顯示根據本創作所實施之瓦斯爐燃燒器的諸裝 置之立體圖; -14- M296961 ι ► _ 第3圖係習知缸體之部分剖面圖,其顯示瓦斯流在及缸 體中之運動; 第4圖係該及缸體之側剖面圖; 第5圖係顯示該瓦斯流在該及缸體中之運動的側剖面 圖; 第6圖係該缸體之中心區域及該瓦斯流之運動的視圖; 第7圖係位在相同側處之該缸體的內側之部分剖面圖; I 第8圖係位在相對側處之該缸體的內側之部分剖面圖; 弟9圖係該缸體之俯視圖; 第1 0圖係根據本創作所實施之該缸體的部分剖面圖, $顯示該內側及該瓦斯流在該中之運動; 第U圖係根據本創作所實施之該缸體的部分剖面圖, 其顯示在該及缸體中之該瓦斯流的所有方向; 第1 2圖係該瓦斯爐燃燒器之習知蓋盤之側剖面圖,其 ®示該瓦斯流之運動; > 第1 3圖係該瓦斯爐燃燒器之習知蓋盤在被翻轉朝下時 之立體圖; 第1 4圖係該瓦斯爐燃燒器之習知蓋盤在被翻轉朝上時 之立體圖; 第1 5圖係根據本創作所實施之該瓦斯爐燃燒器的蓋盤 之部分剖面圖,其顯示該瓦斯流之運動; 第1 6圖係該瓦斯爐燃燒器之蓋盤在被翻轉朝下時之立 體圖; 第1 7圖係根據本創作所實施之該蓋盤的內側的立體圖; -15- M296961 第1 8圖係顯示根據本創 + g」作所貫施之該蓋盤的內側及該 瓦斯流之運動的半剖面圖; 弟1 9圖係在根據本創作所實施之該蓋盤中的該瓦斯流 之運動的視圖;及 第2 0圖係一顯示在該內焰周圍之熱的提升運動之視圖。 【主要元件符號說明】 1 閥M296961 ύ VIII, new description: [New technical field] This paper is about a gas burner, especially for a gas burner, which has a novel gas flow channel to promote gas flow and before combustion Accelerate to achieve more efficient combustion, resulting in more heat, and with a set of hot and cold air (oxygen source) preservation, which can make combustion more complete, consume less gas, reduce soot generated during combustion And pollutants. b [Prior Art] High-pressure gas burners usually have an internal gas-tube shape similar to that of conventional pipelines. The gas tube is connected to a cylinder having a donut shape, a flat surface, and a hollow cylinder portion located at the center of the cylinder. As the gas flows through the gas tube and the cylinder and then surrounds the cylinder portion, it will impact the cylinder-shaped portion in the cylinder and the vertical portion that loses the rate due to the rate of loss in the gas tube. So that a lot of speed is lost. In addition, the gas stream flows along a flat surface of the cylinder that is covered to cover the disk; and I the shape of the cover disk resembles a donut from a top view. A set of holes are provided in the cover disk through which the gas can be diffused upward for combustion. Thus, the inner flat surface of the cover disk will cause the flow of gas flowing through all of the components to lose power and velocity prior to impacting the inner surface of the cover disk before reaching the holes. In addition, the gas flow will first be reflected and lost a large rate before it flows through the gas tube, cylinder and cover disk and before it diffuses upward into the gas holes. This results in less than usual thermal power. Frames with dense solid wings and covered gas burners will prevent cold air from entering the M296961, which will generate soot during combustion. Accordingly, a first object of the present invention is to provide a gas burner burner having an improved aerodynamic internal gas passage structure to reduce gas flow resistance, thereby producing more gas consumption with less gas consumption. heat. A second object of the present invention is to provide a gas burner burner, wherein the gas furnace frame body is designed to force the gas flow from the direction by changing the direction of the gas flow in the cylinder block and the cover disk and adjusting the rate thereof The gas holes are flowed out at a higher speed > rate, so that the maximum heat power can be generated, the gas is consumed less, and the soot generated by incomplete combustion is reduced, thereby developing the gas stove frame body. New content] The above object of the present invention can be achieved by a gas burner provided by the present invention, wherein the ridges and cylinders along the inner gas tube can be used to form a gas flow. An arc-shaped and disproportionate shape like a bowl in the cylinder and a curved ridge inclined at the front and bent to the rear surround the gas flow from the gas pipe, causing the gas flow in the cylinder to change. Direction and directly accelerate the flow to the gas t hole. The dense and solid ridges located at the center of the cylinder help to maintain and heat the inner frame. The inside of the cover disk having respective large and small ridges between the inner and outer gas holes accelerates the gas flow and reduces the reflection force. The sized voids or holes in the wings of the gas hob body allow cold air to enter from the outside for better combustion. [Embodiment] Fig. 1 shows a conventional gas burner burner comprising the following main devices: a valve (1), a venturi opening (2), and an air M296961 i 1 which is used to adjust according to demand. Air conditioning plate (3). Thereby, the gas will flow through the gas pipe (4) into the cylinder (5) and the cover plate (6), and will spread upward to the inner gas hole (?) and the outer gas hole (8) for combustion. The gas hob body (9) can be used to protect against wind and heat. Some types of gas burners may have more than one of the foregoing devices depending on the design and use, such as two valves, two or more gas tubes, multiple cylinder sections, or a plurality of gas orifices. Figure 2 is a diagram showing the apparatus of a gas burner burner implemented in accordance with the present invention. It is similar to the apparatus of a conventional gas burner burner, but differs in that it includes an inner surface and some external components that can flow through the gas. The gas tube (10), the cylinder (11), the cover disk (12) and the upward diffusion to the inner gas holes (1 J ) and the outer gas holes (1 4 ) assist in adjusting the rate of the gas flow and changing the same direction. As a result, the gas flow can be significantly accelerated around the gas holes. In addition, when a plurality of holes (70) are formed in the gas furnace frame body (15), the outside air will be allowed to enter to achieve more complete combustion. Figure 3 is a partial cross-sectional view of a conventional cylinder showing the movement of the gas flow in the gas tube (4) and the cylinder (5). When the gas flow (16) of the conventional gas burner is discharged from the valve or nozzle (1), it will arrive before the cylinder (5) to which the cylinder type portion (17) has been installed. , first through the tile-stube (4). This part of the gas flow will strike the cylinder type (17) in the cylinder. Therefore, the gas flow (16) will lose some degree of rate. Figures 4, 5, 6 and 10 show a cylinder implemented in accordance with the present invention, wherein the internal gas tube (1 〇) is designed to be along the gas tube that is connected to the venturi opening (2) The lower surface (18) and the upper surface (19) have the ridges. The lower ridges (18) have respective large and small dimensions, and the M296961 4% ridges (76) are lifted to the height of the cylinder-shaped portion (η) of the cylinder, and the cylinder-shaped portion The inner surface of the gas tube is enlarged to increase the flow rate and form a gas flow (20) flowing from the venturi opening to the gas tube. The raised ridges are used to divide the gas flow (2〇) into two paths (21) (22) to avoid impacting the cylinder-shaped portion (23) in the cylinder. A certain level of gas flow from the gas tube will flow along the ridges (). Therefore, the gas flow (24) will rise to the height of the cylinder opening on the same side (25) of the gas tube. Figures 4, 5 and 11 show the upper ridges (19) on the inner surface of the gas tube (1) which are separated into two paths before reaching the cylinder (25) (2 6 (27) The gas flow (20) can be separated and formed in the upper side of the gas tube (丨〇). This part of the gas flow will be mentioned below. Figures 4, 5 and 6 show the movement of the gas stream (2 1 ) ( 2 2 ) after flowing through the gas tube (1 〇 ). The gas flow in this portion will rise to the height of the cylinder opening on the same side of the gas tube (25), which is supported by the curved ridges fixed to the sides of the bottom plate of the cylinder (ii), and will Used to flow around the gas flow (2 1 ) ( 2 2 ). These curved ridges are characterized in that they are bent upward at the front side and are slightly bent over the intermediate portion (29) of the cylinder, and the curved slope (30) is raised on the opposite side (33) of the gas tube. To the height of the cylinder. This feature of the curved surface (37) can be used to force the gas flow (2 1 ) ( 2 2 ) that has been split into two paths to change direction and rise to the height of the cylinder opening (25), and The gas flow is significantly accelerated by the upwardly curved portion at the front side. At the same time, the remainder of the gas flow surrounds the cylinder-shaped portion (23) in the cylinder and the curved ramps (29) (30). The gas flow (3 1 ) ( 3 2 ) thus becomes significantly faster than M296961 I fc because of the curved portion of this gas flow on the opposite side (3 3 ) of the gas tube. Figure 3 shows the inside of a conventional cylinder with the same side of the flat gas tube and its opposite side (3 5 ): (3 6 ), which is in the shape of a donut from the top view The velocity of the gas flow (16) around the cylinder-shaped portion (17) in the cylinder is increased because the same (16) flowing along the flat bottom plate moves parallel to the bottom plate and does not It rises to the height of Φ itself. Figures 7 and 8 show the cylinder implemented according to the present invention - wherein the inner wall is circular and curved like a bowl (3 4 ). The variation and increase of the gas flow (2 1 ) ( 2 2 ) ( 3 1 ) ( 3 2 ) is such that the gas flow does not lose a large degree of velocity and can rise to the height of the entire opening. The internal shape of the cylinder is slightly higher than the opposite side of the narrow tube (3 3 ) will rise to the height of the cylinder opening 4 and 5, which is used to flow in the gas (3 1 ) ( 3 2 ) The rate of the gas flow (3 1 ) ( 3 2 ) is increased before the middle portion (38) and the opposite side (3 3) are raised to the cylinder. Figures 9, 10, and 1 show the motion of the stream according to the present creation. The gas flow (3 1 ) moving to the right side is more because the inner side of the cylinder becomes slightly narrower and rises to the height of the cylinder opening at the tile (33) until the same The stream ridge (39) is connected to the surface of the cylinder located around the cylinder opening on the opposite side of the gas tube. These ridges (which flow through the base plate have the same and corresponding portions. In addition, when the circumference is lost to a certain extent, the gas flows through the cylinder opening: the inside of the body can also be used to reduce the lifting force, up to the cylinder narrow And in the wattage, the inner side of the opening of the gas pipe and the wattage of the wattage are accelerated, and the opposite side of the pipe is used to separate the slab (33) at a position of 39 (from the top view - 10 M296961 1 * , Η The viewing is like a wedge, and it looks like a curved slope when viewed from a section. The ridges turn the sharp edge (40) to the direction of the gas flow (31). The sharp end (40) is positioned approximately around the intermediate opening (38) of the cylinder. The ridges (39) are formed into two grooves (4 4 ) where the gas flow (3 1 ) is separated into three paths. The first portion of the gas stream (3 1 ) will rise above the curved portion of the ridges (39) and become the gas flow (4 1 ) at the opening (3 3 ) of the gas tube. . The remainder of the gas flow (31) is forced to separate into two (42) (43) flows directly to the inner gas holes (丨3) located around the opening I (3 3 ) of the gas pipe. And the outer gas hole (; 14), and the gas flow is significantly accelerated because it is compressed and becomes slightly narrower. The gas flow (3 2 ) moving along the two 'grooves (44) on the left side has the same direction as the gas flow (3 1 ). Refer to the directions of the gas flow (73) (74) (75) shown in Figures 9 and 11. Figures 1 and 3 show the cylinder of the conventional gas burner, which has a hole or space (45) in the middle, so that it looks like a donut when viewed from a top view, and the hole or space (45) This will result in a loss of heat generated by the fire trap in the inner gas hole 7) during combustion. Therefore, the gas burner burner will lose some degree of heat around the holes or spaces (45). Figures 10 and 20 show the cylinder of a gas burner according to the present invention, which is designed to provide dense solid holes (47) and curved slopes in the middle of the cylinder (48). And storing the heat of the inner flame (46), and the holes and the curved slopes maintain the heat (50) generated by the inner flame (46) and rotated around the central region (49) of the cylinder, Therefore, the inner flame enhances the hot portion (50) (the increase in heat can be achieved by the dense or different height grooves up to -11-M296961 i* _. The hot portion (5 Ο ) can thus rotate around. The intermediate hole (5 1 ) of the cylinder is used to fix the tie member (52) so that the cylinder can be connected to the face, thereby preventing the gas burner of the gas burner from moving during the operation, Figures 13 and 14 show the cover disk with its internal dimensions (53) and the inner surface (56) flat. When the gas stream (57) flows through the body, it will strike the inner cover disk (56), and the inner cover disk (56) plane is flat. Since the gas flow has largely reflected itself before reaching the inner gas holes (and the outer gas holes (8), the rate of the flow (5 7 ) is reduced. 1 8 and 1 Figure 9 shows the inside of the cover disk implemented according to the present invention, which is characterized by disproportionate design. The inside of the cover (5 4 ) close to the gas pipe has a standard size and is in two sections of vertical and horizontal. The upper portion becomes narrower until the opposite side of the gas tube (5 5 ), and because the flow is compressed, the sections are used to force the gas flow (2 6 ) at the top of the gas tube to accelerate. Until the opposite side of the gas tube (5 5 of the cover disk. > Figures 5, 16 and 17 show that the inner surface of the cover disk is designed to be characterized according to the present invention. Holes (13) (the front ridges (5 9 ) (60) are used to reduce the force under the cover disk and form a gas flow (6 1 ) that flows out of the cylinder and Directly such inner gas holes (1 3 ) and outer gas holes (1 4 ). The gas flow can be in the inner gas holes (1 3 ) and the outer gas holes ( 1 4) pre-acceleration, which is caused by the flow along the ridges (59) (60) that are bent over the gas holes. The gas flow diffused by the gas holes ( 7 2) Then wear the watch in the cylinder: 7) on the gas side, where the disk is slightly out of the tile, and 14) the reflection is shifted to reach the M296961; ^ _ By. Figures 18 and 19 show the inside of the cover disk of the gas burner burner according to the present invention, wherein the ridges (59) are circular and curved. Further, the circular ridges (60) are connected together between the inner gas holes (13) and the outer gas holes (14). The curved and rounded ridges are located on the same side (5 4 )' of the gas tube and are slightly bent up to the opposite side (55) of the gas tube. On these ridges (59) (60), there are respective small and large ridges (62) which are superposed on each other. These ridges (62) turn the small size to the same side (54) of the gas tube. The feature is that the grooves (63) (6 4 ) are formed around the inner gas holes (13) and the outer gas holes (14), which are considered to have 'large and small sizes respectively. The space of gas flow. These spaces are used to compress the flow of gas (2 6 ) (27) from the top of the gas tube, which is preferably as shown in Fig. 18. The gas flow flows out through the grooves (63) (64) around the inner gas holes (13) and the outer gas holes (14) so as to be widely diffused outwardly to the gas holes The rate of the gas flow (26) (27) is increased prior to the opposite side (55) of the gas tube. Please refer to the direction of the gas flow (65) (66) in Figure 19. The ridges (59) (60) (62) are also used to increase the gas flow (2 1 ) ( 22 ) ( 24 ) ( 3 1 ) (32) (41) (42) (43) (73) (74) (75) rate and reduce its reflection force, and the gas flow will flow out from the cylinder opening before reaching the inner gas holes (13) and the outer gas holes (14). Figure 16 illustrates that when using the gas burner, the user can properly place the cover disk on the gas burner. Please refer to the designation (67) which shows that the cover disk is correctly positioned behind the cover disk. M296961. Figure 1 shows a gas stove frame (9) of a conventional gas burner burner having a dense solid wing member (6 8 ) that can be used to store heat on the vessel and to store heat at the beginning of combustion. Since no air or oxygen entered during this operation, the combustion was not completely achieved. In addition, the heat is not complete and soot is produced during combustion. Figure 2 shows a gas stove frame (i 5 ) implemented in accordance with the present invention, which is designed to have the following features: its wings (69) have a configured void size or a suitable set of holes (70), Used to make cold air (7 can be imported from the outside for more complete combustion, reduce soot and prevent food contamination. Therefore, the wing of the gas stove frame (69) is not easy to break. Air flow impinges on this The force on the wing member (69) of the gas furnace frame can be eliminated via these holes (70). Although the present invention is described in detail herein with reference to the preferred embodiments, the above description is for illustrative purposes only. The present invention is not limited thereto, and any modifications and changes can be made without departing from the spirit and scope of the present invention. The scope is defined by the scope of the patent application. The industrial utilization of the creation k gas is a price becoming more and more The higher the rate, the more efficient combustion can be achieved by this gas burner burner, which can save huge energy and reduce environmental pollution if it can be widely used in homes, restaurants, government agencies, restaurants, and industries. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a conventional gas burner; FIG. 2 is a perspective view showing the apparatus of a gas burner according to the present invention; -14- M296961 ι ► _ 3 A partial cross-sectional view of a conventional cylinder showing the movement of gas in the cylinder; Figure 4 is a side cross-sectional view of the cylinder; Figure 5 is a diagram showing the flow of the gas in the cylinder A side view of the movement; Figure 6 is a view of the central region of the cylinder and the movement of the gas flow; Figure 7 is a partial sectional view of the inside of the cylinder at the same side; I Fig. 8 a partial cross-sectional view of the inner side of the cylinder at the opposite side; the top view of the cylinder is shown in Fig. 10; a partial cross-sectional view of the cylinder according to the present invention, $ shows the inner side and The movement of the gas flow therein; the U-figure is a partial cross-sectional view of the cylinder according to the present invention, which shows all directions of the gas flow in the cylinder; the first image is the gas. A side cross-sectional view of a conventional cover of a furnace burner, where the motion of the gas flow is shown; > Figure 13 is a perspective view of the conventional cover disk of the gas burner burner when it is turned down; Figure 14 is a perspective view of the conventional cover disk of the gas burner burner when turned over upward; Figure 5 is a partial cross-sectional view of the gas disk burner according to the present invention, showing the movement of the gas flow; Figure 16 is the cover of the gas burner burner being turned down Fig. 17 is a perspective view of the inner side of the cover plate according to the present invention; -15- M296961 Fig. 18 shows the inside of the cover plate and the inner side of the cover plate according to the present invention a half-sectional view of the movement of the gas flow; a view of the motion of the gas flow in the cover disk implemented in accordance with the present creation; and a second display showing the heat around the inner flame Improve the view of the movement. [Main component symbol description] 1 valve
2 文 氏 管 開口 3 空 氣 調 節板 4 瓦 斯 管 5 缸 體 6 蓋 盤 7 內 瓦 斯 孔 8 外 瓦 斯 孔 9 瓦 斯 爐 架體 10 瓦 斯 管 11 缸 體 12 蓋 盤 13 內 瓦 斯 孔 14 外 瓦 斯 孔 15 瓦 斯 爐 架體 16 瓦 斯 流 17 缸 體 型 部 18 瓦 斯 管 下表面/下突脊 - 16- M296961 .19 瓦斯管上表面/上突脊 20 瓦斯流 2 1 瓦斯流 22 瓦斯流 23 缸體型部 2 4 瓦斯流 25 瓦斯管相同側/缸體開口 26 瓦斯流 • 2Ί瓦斯流 29 缸體中間部分/弧形坡面 ' 30 弧形坡面 3 1 瓦斯流 32 瓦斯流 33 瓦斯管相對側/缸體開口 3 4 碗形 35 對等部分 ® 3 6相稱部分 3 7 彎曲表面 38 瓦斯管中間部分/缸體中間開口 3 9 突脊/圓弧形表面 40 尖銳邊緣 4 1 瓦斯流 42 瓦斯流 43 瓦斯流 -17- M2969612 Venturi opening 3 Air conditioning plate 4 Gas tube 5 Cylinder 6 Cover plate 7 Internal gas hole 8 External gas hole 9 Gas stove frame 10 Gas tube 11 Cylinder block 12 Cover plate 13 Gas hole 14 Outer gas hole 15 Gas Stove body 16 gas flow 17 cylinder type 18 gas pipe lower surface / lower ridge - 16- M296961 .19 gas pipe upper surface / upper ridge 20 gas flow 2 1 gas flow 22 gas flow 23 cylinder type 2 4 gas Flow 25 gas tube same side / cylinder opening 26 gas flow • 2 Ί gas flow 29 cylinder intermediate part / curved slope ' 30 curved slope 3 1 gas flow 32 gas flow 33 gas pipe opposite side / cylinder opening 3 4 bowl shape 35 equivalent part 3 6 proportion part 3 7 curved surface 38 middle part of gas tube / intermediate opening of cylinder 3 9 ridge / arc surface 40 sharp edge 4 1 gas flow 42 gas flow 43 gas flow -17 - M296961
44 溝槽 45 孔或空間 46 內焰 47 孔 48 弧形坡面 49 缸體中心區域 50 熱 5 1 缸體中間部分 52 繫結件 53 內部尺寸 54 蓋盤內側/瓦斯管相同側 55 蓋盤相對側/瓦斯管相對側 56 內蓋盤/內表面 57 瓦斯流 59 突脊 60 突脊 6 1 瓦斯流 62 突脊 63 溝槽 64 溝槽 65 瓦斯流 6 6 瓦斯流 67 標示 68 翼件 -18- M296961 ^ - 69 翼件 70 孔 7 1 冷空氣或氧 72 瓦斯流 73 瓦斯流 74 瓦斯流 75 瓦斯流 76 突脊44 Groove 45 Hole or Space 46 Inner Flame 47 Hole 48 Curved Slope 49 Cylinder Center Area 50 Heat 5 1 Cylinder Intermediate Section 52 Tie 53 Internal Dimensions 54 Cover Plate Inside / Gas Pipe Same Side 55 Cover Plate Relative Side/Gas Tube Opposite Side 56 Inner Cover Plate/Internal Surface 57 Gas Flow 59 Ridge 60 Tire 6 1 Gas Flow 62 Ridge 63 Groove 64 Groove 65 Gas Flow 6 6 Gas Flow 67 Mark 68 Wings-18- M296961 ^ - 69 wing member 70 hole 7 1 cold air or oxygen 72 gas flow 73 gas flow 74 gas flow 75 gas flow 76 ridge