M417190 五、新型說明: 【新型所屬之技術領域】 本實施例侧於-種傭健,特別是—種氣液物裝置。 【先前技術】 隨著衣食住行娛樂社活品質提升,各種交虹具也由腳踏 車、機車升級域車、休旅料,而車輛在馬路上奔馳,難免都 會沾附沙土、塵垢。所以車輛於魏—段時間之後必須進行清 潔1洗,保持車體的潔淨,因此許多車主係都會利用假日將車 輛达至洗麵進行清洗。者於清洗車_作料,侧用泡 棉沾附清軸在切上概,由水管財柱沖洗清潔劑泡 然而’車體於清洗過程中,往往因水管的水柱力量不足,使 仔車體上的塵垢不易清洗乾淨,導致車輛清洗後仍會留下塵垢、 沙土的η卩奸.。 〜 便有業者研發出一空氣喷洗搶或一空氣喷霧槍,利用 兩壓空氣來提升空4噴洗搶妓氣噴霧搶的清潔效果。空氣嘴洗M417190 V. New type description: [Technical field to which the new type belongs] This embodiment is a kind of domestic labor, especially a gas-liquid material device. [Prior Art] With the improvement of the quality of clothing, food, shelter and entertainment, various cross-bows are also upgraded by bicycles and locomotives, and the vehicles are on the road. It is inevitable that the vehicles will be covered with sand and dirt. Therefore, after the Wei-Secret time, the vehicle must be cleaned and washed to keep the car body clean. Therefore, many car owners will use the holiday to clean the car. In the cleaning car _ ingredients, the side with foam dipped in the clear shaft in the cutting, the water pipe to wash the detergent bubble, but the body of the car in the cleaning process, often due to insufficient water column water force, so that the car body The dust is not easy to clean, which will leave dust and sand rust after the vehicle is cleaned. ~ Some operators have developed an air spray rush or an air spray gun, using two pressure air to enhance the cleaning effect of the air spray and smashing the sputum spray. Air mouth wash
=或空氣噴霧搶係利用—Τ形管分別連接-握把、-液體筒及L =嘴’握把底部連接—接管至―空壓機。池控制空壓機的高壓 气、 ^笞内以產生文氏效應(Venturi Effec!;)而將液體筒内 的液體汲ϋ,再㈣嘴向外喷灑。 然而,光靠高壓空氣來提升空氣噴洗搶的清洗能力還是有 ,。並且^氣噴洗搶或空氣噴雜係只具有小面積的噴濃區域。 匕右藉由此空氣喷洗搶或空氣喷霧搶進行車體的清洗時,清 M417190 洗員得需要細4操作,才能確保車體上的所有表面積之塵垢皆 能夠完全地被清洗移除。如此—來,清洗員將需耗#較多的日寺^ 來進行車體的清洗’進而增加卫時成本。並且,單位車體職費 的清潔用水總量也斜目對增加,_提高業者_水成本。、 【新型内容】 本實施例提供-種氣液旋轉噴射裝置,藉簡決空氣喷洗搶 的清洗能力有限,以及_面贿小,使得清洗^較 時間以及較㈣水錄對車體進行清洗,箱提料車的成本。 本實施例所揭露之氣液旋轉噴射裝置,其包含—氣流管、一 擾流管及-液流管。氣辭具有—氣流道,擾流管財-擾流道。 擾流官相接於氣流官,氣流道連通擾流道。擾流道具有一出口端, 出口端具有一賀射路徑,噴射路徑與氣流管的一軸心夾〆銳角。 液流官具有相對的一進液端及一出液端,進液端位於氣流管外。 出液端穿設氣流官至氣流道,且由氣流道延伸至擾流道的出口 端。其中,一高流速氣體由氣流道朝出口端噴送,高流速氣體流 經擾流道’令擾流管因偏心受力而使出口端相對軸心旋轉。一液 體藉由高流速氣體所造成之壓差而由進液端吸引至出液端,液體 並與向>/it速氣體混合霧化而由出口端喷出。 根據上述本實施例所揭露之氣液旋轉喷射裝置,係藉由擾流 管的出口端之噴射路徑與氣流管的軸心失/銳角。因此當高流速 氣體與液體由出口端噴出而對出口端產生一反作用力時,出口踹 受到偏心受力的影響而環繞著氣流管的軸心旋轉。如此,可使得 M417190 亂液旋轉噴射裝置具有較大的魏面積,並同時提升^ 口端所 喷出之清洗水柱的除垢效果。 有關本實施例之詳細特徵與實作,姐合圖式在實施方式中 詳細說明如下’細容足賤任何_目賴術者了解本實施例 之技術内容並據以實施,且根據本制書所揭露之内容及圖式, 任何熟習相關技術者可㈣地理解本實施例相關之目的及優點。 【實施方式】 請參照「第1Α圖」及「第1Β圖」,「第1Α圖」所示為一實 施例之氣液;$疋轉喷射裝置的結構分解剖示圖,「第圖」所示為 貝施例之氣疋轉喷射裝置的結構組合剖示圖。 本實施例之氣液旋轉喷射裝置ΐθ,係可運用於用以清洗車體 勺/月冻1洗核,但不以此為限。氣液旋轉喷射裝置10包^氣流 官110、一擾流管130及一液流管12〇。此外,氣液旋轉噴射裝置 10還可包含一儲液槽150、一氣體壓縮機160及一噴嘴遮罩140。 其中,氣流管110具有一貫通的氣流道111,氣流道111的相 對兩端分別具有一進氣端112及一出氣端113。氣流管110的進氣 端112連接氣體壓縮機160,氣體壓縮機160用以提供高壓高流速 的空氣。 擾流管130具有一擾流道131,擾流道131的徑向截面積係小 於氣流道111的徑向截面積。並且,擾流管130與氣流官110相 連接,使得擾流道131連通於氣流道U1。詳細而言,擾流道131 具有相對的一結合端132與一出口端133 ,擾流道131與氣流道 M417190 111係藉由結合端132連接於出氣端113而相連通。氣體壓縮機 160所提供的高璧高流速空氣可由進氣端ιΐ2依序流過氣流道⑴ 以及擾流道13卜高壓高流速空氣並由出π端133喷出擾流管130 外此外,擾流官13〇係具有折彎結構鄰近於出口端133。更進一 步來說’ A 口端133與結合端132麟位於同一轴線上,使得高 愿局流速空氣由出口端133噴出時的一喷射路徑A與氣流管ιι〇 的一軸心B夹一銳角㊀。 更詳細來說,擾辭13〇係具有相連且相樞接的—彎折管體 1301及-結合管體1302,彎折管體13〇1與結合管體·共同形 成擾流道13卜其中,出口端133位於、彎折管體ΐ3〇ι之一端,結 合端132位於結合管體㈣之—端。此外,擾流管⑽更具有一 套官1303,套管13〇3套住彎折管體13〇1與結合管體·的相接 處。套官13〇3内可具有一軸承結構(未緣示),彎折管體測藉由 套管聰而可平順地相對結合管體·樞轉。當彎折管體· 相對結合管體1迎轉時’出叫133魏縣如B作圓周運 動。當高壓高流速空氣流經擾流道131而至出口端133喷出時, 高壓高流速空氣同時對出口端133產生一反作用力。由於出口端 133並非位於如b上’且噴親徑a也特行於如b,因此 當反作用力作用於.端133時’出口端133料—偏心受力的 狀態而使得彎折管體相對結合管體咖拖轉。 本實施例之液辭12Q縣—可舰辟^具有—液流道 卜以及位於液流道121相對兩端的—進㈣⑵及一出液端 7 M417190 123。其中’進液端122位於氣流管no外,且進液端〖22位於錯 液槽150内。儲液槽150内存放有清洗液152,如水、肥皂液、清 潔液等’液流管120係藉由進液端122來汲取清洗液152。此外, 氣流管110具有形成氣流道111的一環形的側壁114,侧壁114上 具有一穿孔1141連通氣流道η!。液流管12〇的出液端123係經 由穿設過穿孔1141而進入氣流道U!,出液端123並由氣流道ln 延伸至擾流道131的出口端133處。此外,氣流管ι1〇更包含一 止漏件116,止漏件116位於穿孔1141内。止漏件116用以密封 住液流管120與穿孔1141之間的間隙,以避免氣流道ιη内的氣 體由液流管120與穿孔1.141之間的間隙洩漏出來。 此外’本實施例之喷嘴遮罩丨4〇係為一管體,喷嘴遮罩14〇 具有一喷嘴口 143。此外,噴嘴遮罩14〇具有相對的一第一端141 及一第二端142,喷嘴口 143係位於第一端141,且噴嘴遮罩140 的第一端141之開π外徑大於第二端142之開口外徑。噴嘴遮罩 140以第二端142套設於氣流管11〇的出氣端113,使得擾流管13〇 位於喷嘴遮罩140 Μ,擾流管m的出,133對應於嗔嘴口 143。此外,當擾流管130的出口端133繞著軸心Β旋轉時,出口 端133的最大旋轉直徑係小於噴嘴口 143的口徑。 當问壓南流速空氣依序由進氣端112進入氣流道2η、擾流道 131並通過擾流道131内的液流管12〇之出液端123時,擾流道 131内的液.流官120之出液端123處便會產生文氏效應,使得出浪 端123處的塵力小於進液端122處的塵力。如此一來,由於出浪= or air spray grabs use - the Τ tube is connected - the grip, the - liquid cylinder and the L = mouth 'grip bottom connection - take over to the air compressor. The pool controls the high pressure gas of the air compressor, and generates a Venturi effect (Venturi Effec!;) to smear the liquid in the liquid cylinder and then spray the liquid out of the mouth. However, it is still necessary to rely on high-pressure air to improve the cleaning ability of air spray washing. And ^ gas spray wash or air spray system only has a small area of spray area. When using the air spray or air spray to clean the car body, the M417190 washer needs a fine 4 operation to ensure that all surface area dust on the car body can be completely removed. In this way, the cleaner will need to spend more #日寺^ to clean the car body' and increase the cost of the guard. In addition, the total amount of clean water used for the unit's body service costs is also increasing, _ increasing the industry _ water costs. [New content] This embodiment provides a kind of gas-liquid rotary injection device, which has limited cleaning ability by means of simple air blasting, and _ face bribe is small, so that cleaning time is compared with time and (4) water recording is cleaning the vehicle body. The cost of the box picking truck. The gas-liquid rotary injection device disclosed in this embodiment comprises a gas flow tube, a spoiler tube and a liquid flow tube. The words have airflow, spoiler, and spoiler. The spoiler is connected to the airflow officer, and the airflow path is connected to the spoiler. The spoiler has an exit end, and the exit end has a heave path, and the jet path is sharply angled with an axis of the air tube. The liquid flow official has a relatively liquid inlet end and a liquid discharge end, and the liquid inlet end is located outside the gas flow tube. The liquid discharge end passes through the air flow to the air flow path and extends from the air flow path to the exit end of the spoiler. Wherein, a high flow rate gas is sprayed from the air flow path toward the outlet end, and the high flow rate gas flows through the spoiler path, causing the spoiler tube to rotate relative to the axis due to the eccentric force. A liquid is attracted to the liquid discharge end by the liquid inlet end by a pressure difference caused by a high flow rate gas, and the liquid is atomized and mixed with the gas to the >/it gas to be ejected from the outlet end. According to the gas-liquid rotary injection device disclosed in the above embodiment, the injection path of the outlet end of the spoiler is lost/elgle angle to the axis of the gas flow tube. Therefore, when the high flow rate gas and liquid are ejected from the outlet end to generate a reaction force to the outlet end, the outlet port is affected by the eccentric force and rotates around the axis of the gas flow tube. In this way, the M417190 chaotic rotary jetting device has a large Wei area and simultaneously enhances the descaling effect of the washing water column sprayed from the mouth end. Regarding the detailed features and implementations of the present embodiment, the following figures are described in detail in the following embodiments, and the details of the technical contents of the present embodiment are understood and implemented according to the present invention. The contents and the drawings disclosed may be understood by those skilled in the art to understand the objects and advantages of the embodiments. [Embodiment] Please refer to "1" and "1", "1" is a gas-liquid according to an embodiment; the structure of the 疋-jet device is an anatomic view, "图图" A cross-sectional view showing the structure of a pneumatic squirting device of the embodiment of the present invention. The gas-liquid rotary injection device ΐθ of the embodiment can be used for cleaning the body/salt 1 wash core, but not limited thereto. The gas-liquid rotary injection device 10 includes a gas flow commander 110, a spoiler pipe 130, and a liquid flow pipe 12A. In addition, the gas-liquid rotary injection device 10 may further include a liquid storage tank 150, a gas compressor 160, and a nozzle mask 140. The air flow tube 110 has a through air passage 111. The opposite ends of the air passage 111 have an air inlet end 112 and an air outlet end 113, respectively. The gas inlet end 112 of the gas flow tube 110 is coupled to a gas compressor 160 for providing high pressure, high flow rate air. The spoiler 130 has a spoiler 131 having a radial cross-sectional area that is smaller than the radial cross-sectional area of the air passage 111. Further, the spoiler 130 is connected to the airflow member 110 such that the spoiler 131 communicates with the airflow path U1. In detail, the spoiler 131 has an opposite end 132 and an outlet end 133. The spoiler 131 and the air passage M417190 are connected to each other by the joint end 132. The high enthalpy and high flow rate air provided by the gas compressor 160 may sequentially flow through the air flow passage (1) and the turbulent passage 13 and the high pressure and high flow rate air from the intake end ι 2 and be ejected from the spoiler 130 by the π end 133. The flow official 13 has a bent structure adjacent to the outlet end 133. Furthermore, the 'A port end 133 and the binding end 132 are located on the same axis, so that a jet path A when the high velocity air is ejected from the outlet end 133 and an axis B of the air tube ιι are at an acute angle. . In more detail, the spoiler 13 is connected and pivoted - the bent pipe body 1301 and the combined pipe body 1302, and the bent pipe body 13〇1 and the combined pipe body together form the spoiler 13 The outlet end 133 is located at one end of the bent pipe body ΐ3〇ι, and the joint end 132 is located at the end of the joint pipe body (4). In addition, the spoiler tube (10) further has a sleeve 1303, and the sleeve 13〇3 covers the junction of the bent tube body 13〇1 and the joint tube body. The sleeve 13 can have a bearing structure (not shown), and the bent pipe body can be smoothly combined with the pipe body by the casing. When the bent pipe body and the opposite joint pipe body 1 are turned forward, the 133 Wei County is called B for circular motion. When the high pressure and high flow rate air flows through the spoiler 131 to the outlet end 133, the high pressure and high flow rate air simultaneously generates a reaction force to the outlet end 133. Since the outlet end 133 is not located on b, and the spray parent a is also special, such as b, when the reaction force acts on the end 133, the outlet end 133 is eccentrically stressed, so that the bent pipe body is relatively Combined with the tube body tow. In the liquid circulation of the present embodiment, the 12Q county--the ship has a liquid flow path and a (four) (2) and a liquid outlet end 7 M417190 123 located at opposite ends of the liquid flow path 121. Wherein the liquid inlet end 122 is located outside the gas flow tube no, and the liquid inlet end 22 is located in the wrong liquid tank 150. The cleaning liquid 152 is stored in the liquid storage tank 150, such as water, soap liquid, cleaning liquid, etc. The liquid flow tube 120 picks up the cleaning liquid 152 by the liquid inlet end 122. Further, the air flow tube 110 has an annular side wall 114 forming an air flow path 111, and the side wall 114 has a through hole 1141 communicating with the air flow path η!. The liquid discharge end 123 of the liquid flow tube 12 is passed through the perforation 1141 to enter the air flow path U!, and the liquid discharge end 123 is extended by the air flow path ln to the outlet end 133 of the spoiler 131. In addition, the air flow tube ι1〇 further includes a leakage stop 116, and the leakage stop 116 is located in the through hole 1141. The leak stop 116 is used to seal the gap between the flow tube 120 and the perforation 1141 to prevent gas in the air flow path from leaking out of the gap between the liquid flow tube 120 and the perforation 1.141. Further, the nozzle mask 4 of the present embodiment is a tube body, and the nozzle mask 14A has a nozzle opening 143. In addition, the nozzle cover 14 has a first end 141 and a second end 142. The nozzle end 143 is located at the first end 141, and the first end 141 of the nozzle mask 140 has an outer diameter larger than the second diameter. The outer diameter of the opening of the end 142. The nozzle cover 140 is sleeved at the air outlet end 113 of the air flow tube 11'' with the second end 142 such that the spoiler 13 is located at the nozzle mask 140, and the outlet of the spoiler m 133 corresponds to the mouth 143. Further, when the outlet end 133 of the spoiler 130 is rotated about the axis, the maximum rotational diameter of the outlet end 133 is smaller than the diameter of the nozzle opening 143. When the pressure south air flow rate is sequentially entered from the air inlet end 112 into the air flow path 2n, the spoiler 131, and through the liquid flow pipe 12 in the spoiler 131, the liquid in the flow path 131 is disturbed. The Venturi effect is generated at the liquid outlet end 123 of the flow official 120 such that the dust force at the wave end 123 is less than the dust force at the liquid inlet end 122. As a result, due to the waves
M41719U 端123與進液端122之間的屋力差之影響,使得儲液槽⑼内的 清洗液152由進液端122被吸引至出液端123而排出。接著,清 洗液152並與擾流道】31内的高壓高流速空氣混合霧化,並由出 口端133喷出氣液混合的清洗水柱。 在/月洗液152與②⑸流速空氣由出口端⑶喷出的同時, 出口端⑶簡著細B喊轉,使得驗混合的清洗水柱以迴 旋環繞的·不斷噴射。因此,藉由迴旋儒魏的清洗水柱, 可令氣液旋射職置1Q的除魏力增加,並畴提升氣液旋轉 噴射裝置⑴的·面積而增加清洗區域。並且,喷嘴遮罩140係 用以保護擾流管130,以避免擾流管⑽的彎折管體1301相對处 合管體1302於樞轉時,受到外力碰撞而損壞。此外,噴嘴遮罩14〇 更進-步舰了出口端133的喷射翻,_免清洗水桂大範圍 且不受控制的魏,進而影響操作者的作業。 請參照「第2A圖」及「第2β圖」,「第2A圖」所示為另— 實施例之氣職射概置的結構分_示圖,「第2b圖」所示 為另-實施例之·旋轉噴射裝置的結構組合剖示圖。 本實施例之·旋轉噴射裝置2G包含-氣流管210 管230及一液流管22G。此外,氣液旋轉噴射裝置20還可包2 健液槽250、-氣體壓縮機26〇及一嗜嘴遮罩24〇。 其中,氣流管210具有—貫通的氣流道211,氣流道2ΐι的相 對兩端分別具有-進氣端212及—出氣端213。氣流管2iq的進^ 端2!2連接氣體壓縮機·’氣體壓縮機用以提供高壓高流^ 9 M417190 的空氣。 擾流管230為一可撓性軟管,其具有一擾流道231,擾流道 231的徑向截面積係小於氣流道211的徑向截面積。並且,擾流管 230與氣流官210相連接’使得擾流道231連通於氣流道211。詳 細而§,擾流道231具有相對的一結合端232與一出口端,優 流道231與氣流道211係藉由結合端232連接於出氣端213而相 連通。氣體壓縮機260所提供的高壓高流速空氣可由進氣端212 依序流過氣流道211以及擾流道231,高壓高流速空氣並由出口端 233喷出擾流管230外。此外,擾流管23〇上並套設有多個荷重環 234,荷重環234鄰近於出口端233,荷重環234帛以增加擾流管 230之出口端233的負重。出口端233因受負重的影響而彎曲下 垂’使得出口端233與結合端232並非位於同—轴線上。由於出 :端233與結合端232並非位於同—軸線上,使得高㈣流速空 氣由出口端233噴出時的一喷射路徑a與氣流管21〇的一軸、' b 夾一銳角Θ。 當咼壓高流速空氣流經擾流道231而至屮n ^ 〜233喷出時, 尚壓尚流速空氣同時對出口端233產生一反竹田a 用力。由於出口端 並非位於軸心B上,且噴射路徑A也非 本G a 丄 订於軸心B,因此 虽反作用力作用於出口端233時,出口端233 # & UK a. , '丁'為一偏心受力的 狀悲。由於擾流管230係為可撓曲的軟管,田a , ^此出D端# ra 偏心受力而相對軸心B旋轉。 本實施例之液流管220係為一可撓性款營 ,其具有一液流道 M417190 221,以及位於液流道221相對兩端的一進液端222及一出液端 223。其中,進液端222位於氣流管210外,且進液端222位於儲 液槽250内。儲液槽250内存放有清洗液252,如水、肥皂液、清 潔液等,液流管220係藉由進液端222來汲取清洗液25>此外, 氣流管210具有形成氣流道211的一環形的側壁214,側壁214上 具有一牙孔2141連通氣流道211。液流管220的出液端223係經 由穿設過穿孔2141而進入氣流道211,出液端223並由氣流道211 鲁延伸至擾流道231的出口端233處。此外,氣流管21〇更包含一 止漏件216,止漏件216位於穿孔2141内。止漏件210用以密封 住液流管220與穿孔2141之間的間隙,以避免氣流道211内的氣 體由液流管220與穿孔2141之間的間隙洩漏出來。 此外’本實施例之噴嘴遮罩24〇係為一管體,噴嘴遮罩24〇 具有一噴嘴口 243。此外,噴嘴遮罩240具有相對的一第一端241 及一第二端242 ’噴嘴口 243係位於第一端241,且噴嘴遮罩240 ®的第一端241之開口外徑大於第二端242之開口外徑。噴嘴遮罩 240以第二端242套設於氣流管21〇的出氣端213,使得擾流管230 位於噴嘴遮罩240内,擾流管230的出口端233對應於噴嘴口 243。並且,噴嘴遮罩24〇係用以限制住出口端233繞著軸心B旋 轉時的旋轉直徑。 當高壓高流速空氣依序由進氣端212進入氣流道21卜擾流道 231並通過擾流道231内的液流管22〇之出液端223時,擾流道 231内的出液端223處便會產生文氏效應,使得出液端223處的壓 M417190 力小於進液端222處_力。如此—來,由於出液端扭应進液 端222之間的壓力差之影響,使得儲液槽25〇内的清洗液况由 進液端222被吸引至出液端223而排出。垃泣.^ J饼。接者,清洗液252並與 擾流道231内的空氣混合霧化,並由出 上田口為233噴出氣液混合的 清洗水柱。 藉由上述之懸管23〇為可触f體之紐,使職流管23〇 不需具有兩相樞接的管體結構設計,即可使出〇端233能夠繞著 軸心B作圓周運動。如此一來,也可節省氣液旋轉喷射裝置㈣ 材料成本。 .根據上述實施例所揭露之驗旋轉噴射裝置,係藉由擾流管 的出口端之噴射路徑與氣流管的軸心夾—銳角。因此當清洗水柱 由出口射出時’出口端係因偏心受力而環繞著氣流管的轴心旋 轉。因此’藉由出口端的旋轉設計,而使得氣液旋轉喷射裝置具 有較大的鯓面積’並同時提升由出口稿噴出之清洗水枝的除 垢效果。 ▲雖然本實關揭露如上所述,然並_嫌定本實施例,任 何^相職藝者,林麟本實_之精神和範_,舉凡依 *月辜巳圍所述之形狀、構造、特徵及精神當可做些許之變更,因 此本貫施例之專鄉護範圍須視本賴書所社暢專利範圍所 界定者為準。 【圖式簡單說明】 第ΙΑ ®所不為一實施例之氣液旋轉嗔射裝置的結構分解剖 M417190 示圖。 第1B圖所示為一實施例之氣液旋轉噴射裝置的結構組合剖 示圖。 第2A圖所示為另一實施例之氣液旋轉噴射裝置的結構分解 剖示圖。 .第2B圖所示為另一實施例之氣液旋轉噴射裝置的結構組合 剖示圖。 【主要元件符號說明】The influence of the difference in the force between the M41719U end 123 and the liquid inlet end 122 causes the cleaning liquid 152 in the liquid storage tank (9) to be sucked by the liquid inlet end 122 to the liquid discharge end 123 to be discharged. Next, the cleaning liquid 152 is mixed and atomized with the high-pressure high-flow air in the spoiler 31, and the gas-liquid mixed washing water column is ejected from the outlet end 133. While the / month washing liquid 152 and the 2 (5) flow rate air are ejected from the outlet end (3), the outlet end (3) is simply bounced, so that the mixed washing water column is continuously swirled around the revolving water. Therefore, by rotating the water column of Ruwei, the gas-liquid spinning position 1Q can be increased by the addition of Wei force, and the area of the gas-liquid rotary injection device (1) can be increased to increase the cleaning area. Further, the nozzle cover 140 is used to protect the spoiler 130 from the fact that the bent pipe body 1301 of the spoiler pipe (10) is damaged by an external force when it is pivoted relative to the pipe body 1302. In addition, the nozzle cover 14〇 further enters the jet vent of the exit end 133, and the _ no-clean water is widely controlled and uncontrolled, thereby affecting the operator's work. Please refer to "2A" and "2β", "2A" for the structure of the gas-fired projections of the other embodiment, and the "2b" for the other For example, a structural sectional view of a rotary injection device. The rotary injection device 2G of the present embodiment includes a gas flow tube 210 tube 230 and a liquid flow tube 22G. In addition, the gas-liquid rotary injection device 20 can also include a health bath 250, a gas compressor 26, and a mouthpiece cover 24A. The air flow tube 210 has a through air passage 211, and the opposite ends of the air passage 2 具有 have an air inlet end 212 and an air outlet end 213, respectively. The inlet 2! 2 of the gas flow tube 2iq is connected to the gas compressor. The gas compressor is used to supply high pressure and high flow air of 9 M417190. The spoiler 230 is a flexible hose having a spoiler 231 having a radial cross-sectional area that is smaller than a radial cross-sectional area of the airflow path 211. Further, the spoiler 230 is connected to the airflow member 210 so that the spoiler 231 communicates with the airflow path 211. In detail, the spoiler 231 has a combined end 232 and an outlet end, and the flow path 231 and the air flow path 211 are connected to the air outlet 213 by the joint end 232. The high pressure and high flow rate air provided by the gas compressor 260 can be sequentially flowed through the air flow path 211 and the spoiler path 231 by the intake end 212, and the high pressure and high flow rate air is ejected from the outlet end 233 outside the spoiler tube 230. In addition, the spoiler 23 is sleeved and sleeved with a plurality of load rings 234, the load ring 234 is adjacent to the outlet end 233, and the load ring 234 is increased to increase the load of the outlet end 233 of the spoiler 230. The outlet end 233 is bent under the influence of the load so that the outlet end 233 and the joint end 232 are not located on the same axis. Since the end 233 and the joint end 232 are not located on the same axis, a jet path a when the high (four) flow rate air is ejected from the outlet end 233 is an acute angle 与 with the axis of the air tube 21〇. When the high-flow air flows through the spoiler 231 and is ejected to 屮n^~233, the air is still flowing at the same time, and the anti-bamboo a is generated at the outlet end 233. Since the outlet end is not located on the axis B, and the injection path A is not the same as the axis B, the outlet end 233 # & UK a. , '丁' when the reaction force acts on the outlet end 233 For an eccentric force. Since the spoiler 230 is a flexible hose, the field a, ^ the D end # ra is eccentrically stressed and rotates relative to the axis B. The flow tube 220 of the present embodiment is a flexible one having a liquid flow path M417190 221 and a liquid inlet end 222 and a liquid discharge end 223 at opposite ends of the liquid flow path 221. The liquid inlet end 222 is located outside the gas flow tube 210, and the liquid inlet end 222 is located in the liquid storage tank 250. The liquid storage tank 250 stores a cleaning liquid 252 such as water, soap liquid, cleaning liquid, etc., and the liquid flow tube 220 picks up the cleaning liquid 25 by the liquid inlet end 222. Further, the air flow tube 210 has a ring shape forming the air flow path 211. The side wall 214 has a hole 2141 communicating with the air passage 211 on the side wall 214. The liquid outlet end 223 of the flow tube 220 passes through the perforation 2141 and enters the air flow path 211, and the liquid discharge end 223 extends from the air flow path 211 to the outlet end 233 of the spoiler path 231. In addition, the air flow tube 21 further includes a stop member 216, and the stop member 216 is located in the through hole 2141. The leak stop 210 is used to seal the gap between the liquid flow tube 220 and the perforation 2141 to prevent the gas in the air flow path 211 from leaking out of the gap between the liquid flow tube 220 and the perforation 2141. Further, the nozzle mask 24 of the present embodiment is a tube body, and the nozzle mask 24 has a nozzle opening 243. In addition, the nozzle cover 240 has an opposite first end 241 and a second end 242. The nozzle opening 243 is located at the first end 241, and the opening outer diameter of the first end 241 of the nozzle mask 240 is larger than the second end. 242 opening diameter. The nozzle cover 240 is sleeved at the outlet end 213 of the gas flow tube 21A with the second end 242 such that the spoiler tube 230 is located within the nozzle shield 240, and the outlet end 233 of the spoiler tube 230 corresponds to the nozzle opening 243. Also, the nozzle cover 24 is used to limit the rotational diameter of the outlet end 233 as it rotates about the axis B. When the high pressure and high flow rate air sequentially enters the air passage 21 and the flow passage 231 from the intake end 212 and passes through the liquid outlet 22 of the flow tube 22 in the spoiler 231, the liquid discharge end in the spoiler 231 A Venturi effect occurs at 223 such that the pressure M417190 at the liquid outlet 223 is less than the force at the inlet end 222. As a result, the cleaning liquid condition in the liquid storage tank 25 is sucked by the liquid inlet end 222 to the liquid discharge end 223 and discharged due to the influence of the pressure difference between the liquid discharge end and the liquid inlet end 222. Weep. ^ J cake. In addition, the cleaning liquid 252 is mixed and atomized with the air in the spoiler 231, and a cleaning water column in which the gas and liquid are mixed is discharged from the upper port. The above-mentioned suspension tube 23 is a contactable body, so that the service flow tube 23 does not need to have a two-phase pivotal tube structure design, so that the exit end 233 can make a circumference around the axis B. motion. In this way, the material cost of the gas-liquid rotary injection device (4) can also be saved. According to the above embodiment, the rotary injection device is formed by the injection path of the outlet end of the spoiler tube and the axis of the air flow tube - an acute angle. Therefore, when the washing water column is ejected from the outlet, the outlet end is rotated around the axis of the gas flow tube due to the eccentric force. Therefore, the gas-liquid rotary injection device has a large crucible area by the rotation design of the outlet end and simultaneously enhances the descaling effect of the washing water branch sprayed from the outlet. ▲Although this actual disclosure is as described above, and _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ And the spirit can be changed a little, so the scope of the local protection of the local application shall be subject to the definition of the patent scope of the company. [Simple description of the diagram] The structure of the gas-liquid rotary squirting device of the first embodiment is not divided into an M417190 diagram. Fig. 1B is a cross-sectional view showing the structure of a gas-liquid rotary injection device of an embodiment. Fig. 2A is a cross-sectional view showing the structure of a gas-liquid rotary injection device of another embodiment. Fig. 2B is a cross-sectional view showing the structure of a gas-liquid rotary injection device of another embodiment. [Main component symbol description]
10 氣液旋轉噴射裝置 110 氣流管 111 氣流道 112 進氣端 113 出氣立而 114 侧壁 1141 穿孔 116 止漏件 120 液流管 121 液流道 122 進液端 123 出液端 130 擾流管 1301 彎折管體 1302 結合管體 M417190 1303 套管 131 擾流道 132 結合端 133 出口端 140 喷嘴遮罩 141 第一端 142 第二端 143 .噴嘴口 150 儲液槽 152 清洗液 160 氣體壓縮機 20 氣液旋轉喷射裝置 210 氣流管 211 氣流道 212 進氣端 213 出氣 214 側壁 2141 穿孔 216 止漏件 220 液流管 221 液流道 222 進液端 223 出液端10 gas-liquid rotary injection device 110 air flow tube 111 air flow channel 112 air inlet end 113 air outlet vertical 114 side wall 1141 perforation 116 leakage stop 120 liquid flow tube 121 liquid flow channel 122 liquid inlet end 123 liquid outlet end 130 spoiler tube 1301 Bent pipe body 1302 combined pipe body M417190 1303 bushing 131 spoiler 132 joint end 133 outlet end 140 nozzle shield 141 first end 142 second end 143. nozzle port 150 reservoir 152 cleaning fluid 160 gas compressor 20 Gas-liquid rotary injection device 210 gas flow tube 211 air flow channel 212 air inlet end 213 gas outlet 214 side wall 2141 perforation 216 stop stop 220 liquid flow tube 221 liquid flow path 222 liquid inlet end 223 liquid outlet end
14 M417190 230 擾流管 231 擾流道 232 結合端 233 出口端 234 荷重環 240 喷嘴遮罩 241 第一端 242 第二端 243 喷嘴口 250 儲液槽 252 清洗液 260 氣體壓縮機14 M417190 230 spoiler 231 spoiler 232 joint end 233 outlet end 234 load ring 240 nozzle mask 241 first end 242 second end 243 nozzle port 250 reservoir 252 cleaning fluid 260 gas compressor