201021713 六、發明說明: 【發明所屬之技術領域】 本發明是關於,將草苺、栗子等的水果或水煮蛋等的 固態物供應至饅頭等的糕餅或漢堡等的調理食品的內部來 製造包覆食品之製造裝置以及製造方法。詳而言之,是關 於用來製造內包有2個以上的固態物之製造裝置及裝造方 法。 【先前技術】 中國的傳統點心有一種內包2個鹹鴨蛋黃的月餅(稱 爲雙蛋黃月餅)。鹹鴨蛋黃是將鴨蛋黃鹽漬而成的固態物 。雙蛋黃月餅,一般是被模壓成型成圓盤形狀或長方體( 底面正方形)。該月餅較佳爲,2個鹹鴨蛋黃被包覆成從 月餅中心分別朝左右(半徑方向)均等地分離。 專利文獻1記載一種用來製造內包有2個固態物之包覆 φ 食品的製造裝置(包餡機)。該包餡機具備:外筒、內筒 及中心筒是形成同心圓狀的疊合嘴。在疊合嘴的上部具備 固態物供應裝置。在疊合嘴的下方具備包覆切斷裝置。再 者,在包覆切斷裝置的下方具備:作爲搬運裝置之帶式輸 送機。而且,在搬運裝置的下游側具備:將包覆食品實施 .模壓成型之模壓機。 該固態物供應裝置,是設有可旋轉自如且隔著既定間 隔形成有收容孔(以2個固態物爲1組進行收容)之旋轉盤 。從該固態物供應裝置將成爲1組的2個固態物間歇地供應 -5- 201021713 給疊合嘴的中心筒。接著’從疊合嘴吐出三層構造的棒狀 食品(由固態物、被覆固態物的內材、被覆內材的外皮材 所構成)。然後,藉由包覆切斷裝置從棒狀食品切斷成內 包有2個固態物之包覆食品。這時’ 2個固態物是在包覆食 品的內部以上下方向重疊的方式密合在一起。 然後,用人工等切換該包覆食品的方向而使前述上下 方向朝向搬運方向(水平方向)。之後’藉由前述壓模機 將包覆食品實施壓模成型。這時’必須經由手工作業等來 調整包覆食品的方向性,因此期望能提昇製造效率。此外 ,該包覆食品內的2個固態物’由於是在固態物彼此密合 的狀態下用模具實施擠壓變形,因此固態物彼此可能無法 分離。此外,即使固態物彼此可分離的情況,由於固態物 彼此的密合程度並非一定,而存在著固態物彼此的間隔不 穩定的問題。此外,由於在2個固態物之間形成有空隙, 在烘烤時包覆食品可能發生破裂(內部空氣因加熱而膨脹 ,造成包覆食品破裂)的問題。特別是,在包覆食品爲雙 蛋黃月餅的情況,會導致其商品價値明顯降低的問題。因 此,以往的雙蛋黃月餅,只能採用人工製造的方法,而期 望提供出可提昇生產效率之製造裝置及製造方法。 〔專利文獻1〕中國實用新型專利268 63 46號說明書 【發明內容】 在製造內包有2個以上的固態物(或是2群以上的固態 物群)的包覆食品時’存在著固態物彼此無法分離的問題 -6 - 201021713 、固態物彼此的間隔不穩定的問題。此外,由於在固態物 的周圍形成有空隙,在加熱處理時可能發生包覆食品破裂 的問題。 本發明是有鑑於前述問題而提供的內包有複數個固態 物之固態物包覆食品之製造裝置,其特徵在於,具備:具 有疊合嘴的包餡機、以及對該包餡機同時供應前述複數個 固態物之固態物供應裝置;前述疊合嘴具備:具有讓複數 Φ 個固態物個別降下的通路之管構件、以及圍繞該管構件之 嘴構件。 此外,該固態物包覆食品之製造裝置的特徵在於:前 述嘴構件的吐出口的形狀,是沿著前述管構件的通路之配 置方向具有長軸。 此外,前述固態物包覆食品之製造裝置的特徵在於: 具備可在前述管構件中進行上下移動之活塞,在該活塞的 下面具備將前述複數個固態物往其等的中心擠壓之擠壓面 ❹ 此外’前述固態物包覆食品之製造裝置的特徵在於: 具備可在前述管構件中進行上下移動之活塞,使該活塞與 從前述活塞的前端吸引空氣之吸引裝置連通。 依據本發明,在從內包有複數個固態物之棒狀食品將 包覆食品實施包覆切斷時,能使前述固態物以不互相密合 的方式沿水平方向配置於前述棒狀食品內。 此外’能使固態物與被覆其的食品材料密合。 本申請案是根據2008年11月18日申請之日本特願 201021713 2008-294984號及2009年5月8日申請之日本特願2 00 9-113173號而提出的,其內容是形成本申請案的內容的—部 分。 此外,透過以下詳細的說明即可更完全地理解本發明 。然而’詳細說明及特定實施例僅是本發明之較佳實施形 態,是爲了作說明所記載的。根據該詳細說明的內容所進 行之各種的變更、修改,對熟習此技藝人士而言是相當明 顯的。 申請人無意將所記載的實施形態中的任一個獻給公眾 。在所揭示的改變、替代案當中,即使是申請專利範圍之 字面上所無法包含的,也是構成均等論下的發明的一部分 〇 在本說明書及申請專利範圍的記載中名詞及相同指示 代名詞的使用,在沒有特別指示的情況下,或依文脈沒有 明白否定的情況下,應解釋成包含單數及複數雙方。本說 明書所提供之例示或例示用語(例如「等」)的使用也是 ’不過只是爲了容易說明本發明而已,在未記載於申請專 利範圍的情況下,並非對本發明的範圍施加限制。 【實施方式】 使用第1圖至第3圖來說明本發明的第1實施形態之包 覆食品製造裝置1。包覆食品製造裝置1具備包餡機2。包 餡機2具備架台3。在該架台3的上面具備:用來收容內包 材5(食品材料)的內包材用料斗7、用來收容外皮材9( -8 - 201021713 食品材料)的外皮材用料斗11。內包材供應裝置15是配置 在BU述內包材用料斗7的下側。在該內包材供應裝置15內 收藏螺桿8及葉輪泵1〇。此外,外皮材供應裝置17是配置 在外皮材用料斗11的下側。在該外皮材供應裝置17內收藏 螺桿12及葉輪泵14。再者,疊合嘴13是配置在內包材供應 裝置15和外皮材供應裝置17之間。 包覆切斷裝置21,是設置在前述疊合嘴13的下方。此 φ 外,前述疊合嘴13可吐出三層構造的棒狀麵團19;該棒狀 麵團19,是將2個固態物A、固態物B的外側用前述內包材5 被覆’在前述內包材5的外側疊合外皮材9而構成。該包覆 切斷裝置21,是從前述棒狀麵團19將內包有前述固態物A 、固態物B之包覆食品23實施包覆切斷。 輸送裝置25,是設置在前述包覆切斷裝置21的下方。 該輸送裝置25具有無端狀的平坦帶體。該平坦帶體,是用 來搬運前述包覆食品23之輸送帶25A,捲繞在驅動滑輪25B φ 等而歇間地運行。此外,上下動板26,是在前述疊合嘴13 的下方位置,可上下移動地設置在前述輸送帶25 A的內側 。隨著該上下動板26的上下移動,前述輸送帶25A的搬運 面的一部分也會上下移動。在此,也稱爲輸送裝置25上下 移動。 此外,前述內包材供應裝置15、外皮材供應裝置17、 包覆切斷裝置21及輸送裝置25’由於採用公知的構造即可 ,因此省略其構造之詳細說明。 接著參照第4圖至第9圖來作說明。前述疊合嘴13具有 -9 - 201021713 上部殼體31和下部殼體33。上部殻體31具備外筒32和內筒 35。該外筒32的側部分別具有連接口 32A及連接口 32B (參 照第7圖)。該連接口 32 A與前述內包材供應裝置15連通。 此外,該連接口 32B與前述外皮材供應裝置17連通。在前 述外筒32的內側,具備與外筒32的筒部32C呈同心狀的內 筒35。該內筒35是中空的,其筒部的側面開口與前述連接 口 32A連通。該內筒35是形成能讓前述內包材5通過。在前 述外筒32的筒部32C的內周面與前述內筒35的外周面之間 形成環狀的空間R1。該環狀的空間R1與前述連通口 32B連 通。因此,前述外筒32的內部是形成可讓前述外皮材9通 再者,在前述內筒35內側設置導入導件37。該導入導 件37,是用來將固態物導引至前述疊合嘴13的下方位置的 構件。該導入導件37具有凸緣構件39。該凸緣構件39 ’相 對於凸緣構件39的中心線呈對稱地形成有2個貫通孔39A、 3 9B。導入導件37具有相同形狀的2個管構件41A、41B。2 Q 個管構件41A、41B的各上端部分別嵌入前述貫通孔39A、 3 9B,且被螺絲固定於適當的位置。此外,在前述凸緣構 件3 9的上面安裝定位用的銷構件43。在本實施形態’該銷 構件43的配置方向與前述貫通孔39A、39B的配置方向正交 〇 此外,在前述凸緣構件39的凸緣部39C的下面形成定 位用的突條部39D。該突條部39D,相對於凸緣構件39之 鉛垂方向的中心線,是配置在與前述銷構件43的配置方@ -10- 201021713 相同的方向。而且,在前述內筒35的上端部,形成與該突 條部39D嵌合之凹狀狹縫35A。此外,在內筒35的下端部 螺合內包材用嘴45。前述凸緣構件39,是從上方嵌入前述 內筒35的內側,在前述凸緣部39C被載置於前述內筒35上 面的狀態下,藉由螺帽構件83固定於內筒35。 下部殻體33具有外皮材用嘴47及外殼49。該外皮材用 嘴47是從外殼49的下方進行嵌合,並藉由螺帽構件51固定 φ 住。藉由將該外殻49安裝在前述外筒32的下面,以將前述 外皮材用嘴47配置成圍繞前述內包材用嘴45。因此,在內 包材用嘴45的外周面與外皮材用嘴47的內周面之間形成環 狀的空間R2,環狀空間R2與形成於前述上部殼體31之環狀 空間R1連通,藉此在前述疊合嘴13的內部形成讓外皮材9 通過的環狀空間R。 在前述上部殼體31和前述下部殼體33之間,可旋轉自 如地設置攪拌旋轉構件27 (與未圖示的驅動裝置可連動地 U 連結)。該攪拌旋轉構件27具備攪拌構件27A,該攪拌構 件27 A被配置成可在前述環狀空間R內旋轉。該攪拌旋轉構 件27,是用來攪拌通過前述環狀空間R的外皮材9。 如第8 (a)圖所示,前述內包材用嘴45的內周面,是 具有可讓前述2個管構件41A、41B貫穿的大小。此外,前 述內包材用嘴45的吐出口 45A是形成長圓形。再者’前述 外皮材用嘴47的吐出Π47Α也是形成長圓形。而且’前述 吐出口 45A的長軸及前述吐出口 47A的長軸分別是沿著前 向 方 平 水 ΓΝ 向 方 置 配 的 B IX 4 ' A 4 件 構 管 個 2 述 外 此 -11 - 201021713 前述吐出口 45A及前述吐出口 47A的形狀亦可爲橢圓形。 前述吐出口 45A和前述吐出口 47A的間隙,是在全周形成 大致相同。 接著說明,前述內包材用嘴45及前述外皮材用嘴47對 於前述管構件41A、41B的定位機構。在前述內包材用嘴45 的側面,相對於內包材用嘴45的鉛垂方向中心線,將2根 定位銷53螺合在對稱位置。此外,在前述外皮材用嘴47的 上部內周面之2個部位,形成供前述銷53嵌合的凹狀的嵌 合溝槽47B(參照第5圖)。再者,將定位用銷55壓入前述 外皮材用嘴47的上部外周面。在本實施形態,該銷55被安 裝在:與2個前述嵌合溝槽47B的形成方向(水平方向)正 交的水平方向。而且,在前述外殼49的內周面,形成有供 前述外皮材用嘴47的銷55嵌合之凹狀的嵌合溝槽49B。 固態物供應裝置57,是可拆裝自如地載置在前述疊合 嘴13的上部。該固態物供應裝置57具備座部59。該固態物 供應裝置57,是藉由緊固螺釘61將座部59的基端部5 9A( 第2圖的左側)安裝在包餡機2。在座部59的座板5 9B的上 面,藉由螺釘來拆裝自如地安裝盆狀的托盤63。在該托盤 63的底面形成位於前述疊合嘴13上方的開口 63A。再者, 旋轉盤65是設置於前述托盤63的內側。 在前述座板5 9B的下面設置:用來間歇地旋轉驅動前 述旋轉盤65之驅動裝置。該驅動裝置,可採用公知的機構 ,例如可使用伺服馬達等的電動馬達或棘輪機構等。而且 ,前述旋轉盤65,是藉由緊固螺釘67而可拆裝地安裝在前 201021713 述驅動裝置的旋轉軸69。 則述旋轉盤65’在圓周P上等間隔地形成24個收容孔 65 A。再者,前述旋轉盤65,在比前述圓周P小徑的圓周Q 上等間隔地形成24個收容孔65B。亦即,前述旋轉盤65, 是以某個收容孔65A和與該收容孔65A鄰接的其中一方的 收容孔65B爲一組’而具備24組的收容孔。而且,前述旋 轉盤65’是藉由前述旋轉軸69的旋轉,以每次旋轉15度的 φ 方式間歇地朝一方向(第3圖的逆時針方向)旋轉。藉由 在前述收容孔65A、65B內收容固態物A、固態物B,且讓 前述旋轉盤65間歇旋轉,以將固態物A、固態物B間歇地供 應至前述疊合嘴13內。 此外,前述固態物供應裝置57,是在前述旋轉盤65及 前述疊合嘴13的上方設置推入裝置71。該推入裝置71,是 用來將供應至前述疊合嘴13內的固態物A、B推到前述疊合 嘴13的下方位置。該推入裝置71具有支架73。該支架73, φ 是設置在前述托盤63和前述緊固螺釘61之間,且以長邊方 向朝鉛垂方向的方式安裝在前述座部59。再者,作爲直動 式致動器之無桿式氣缸75,被固定在前述支架73的一側面 。該無桿式氣缸75被配置成,使其滑動件75A的移動方向 沿著鉛垂方向。而且,在滑動件75 A上,藉由保持具75B安 裝2根桿件77A、77B。2根桿件77A、77B配置成互相平行 ,且其長邊方向是沿著鉛垂方向。在前述桿件77 A及桿件 77B的各下端部,分別螺合活塞78A、78B。活塞78A、78B 被配置成,可分別插通在停止旋轉後的前述旋轉盤65的前 -13- 201021713 述收容孔65A及收容孔65B。 此外’前述桿件77A、77B及前述活塞78A、78B是形 成中空狀,前述桿件77A、77B的上端部是連通於未圖示的 吸引裝置。 接著說明前述固態物供應裝置5 7和前述疊合嘴13的定 位機構。在前述固態物供應裝置57的座板59B的下面安裝 凸緣構件79。該凸緣構件79具有2個貫通孔79A、7 9B。各 貫通孔79A、79B被配置成:分別與停止旋轉後的旋轉盤65 的各收容孔65A、65B—致。此外,在前述凸緣構件79的下 面形成嵌合凹部7 9C。在該嵌合凹部79C的底面形成定位用 的嵌合孔79H。該嵌合凹部79C是與前述叠合嘴13的導入導 件37的凸緣構件39的上端部嵌合。這時,前述嵌合孔7 9H 是與前述疊合嘴13的銷構件43嵌合而進行定位。 如此般在前述疊合嘴和前述固態物供應裝置構成定位 機構,以將各通路組合成朝向同一方向而讓前述固態物可 通過前述固態物供應裝置及前述疊合嘴內。前述推入裝置 71的桿構件77A ' 77B、前述旋轉盤65的收容孔65A、65B 、前述疊合嘴13的管構件41A、41B等,從俯視觀察是配置 成大致同心狀。此外,可讓內包材用嘴45的吐出口 45A及 外皮材用嘴47的吐出口 47A的方向性與上述各構件的方向 性一致。換言之,能讓內包材用嘴45的吐出口 45 A及外皮 材用嘴47的吐出口 4 7A的長軸與管構件41A、41B的配置方 向在水平方向一致。再者,在將各構件組裝在包覆食品製 造裝置1的本體時,容易進行其等的位置對準。 -14 - 201021713 此外,在前述內筒35的內部可沿上下方向移動自如地 設置防振板81。在該防振板81的內部形成長圓形的插通孔 81A。在該插通孔81A插通前述管構件41A、41B。該防振 板81的作用在於,當各活塞78A、78B分別在管構件41A、 41B的內部上下移動時,可防止管構件41A、41B發生朝半 徑方向的振動。 在此說明本發明的第1實施形態之包覆切斷的步驟。 φ 在此的包覆食品是指雙蛋黃月餅,其外皮材使用月餅麵團 ,內包材使用餡,固態物使用鹹鴨蛋黃。 從疊合嘴13的下方吐出內包材5及外皮材9的狀態開始 說明。從外皮材用嘴47的吐出口 47 A吐出棒狀麵團19。該 棒狀麵團19,是用外皮材9被覆內包材5之雙層構造。內包 材5,是通過內包材用嘴45的內周面和導入導件37的2根管 構件41A、41B的外周面之間而從該內包材用嘴45的吐出口 45 A吐出。這時,在呈棒狀吐出之內包材5的內部形成:2 φ 根圓柱形且具備底部的袋狀空間5A、5B。 這時,固態物供應裝置57的旋轉盤65往箭頭T方向旋 轉15度後再度停止。如此,固態物A、B會從旋轉盤65的收 容孔65 A、65B同時落下,而個別供應至前述內包材5的空 間5A、5B。而且,在前述旋轉盤65停止的同時,驅動前述 推入裝置71的無桿氣缸,使停止於上昇位置的各活塞78A 、78B分別沿收容孔65A、65B、導入導件37的通路(貫通 孔39A及管構件41A、貫通孔39B及管構件41B)的內部往 下降。這時,在通路內有固態物滯留的情況,前述活塞 -15- 201021713 78A、78B可將固態物A、b推到下降位置,而能對袋狀的 前述空間5A、5B穩定地供應固態物a、B。此外,由於前 述活塞78A、78B將固態物a、B推到袋狀的前述空間5A、 5B的底部’而能讓固態物a、b的下方部分密合於內包材5 。此外’由於在2個固態物a、B之間介入前述內包材5,在 棒狀麵團19的內部固態物a、B彼此不會接觸,而在水平方 向配置成互相分離。 . 下降至下降位置後的前述活塞78A、78B,再度上昇。 在前述活塞78A、78B上昇的前後,或上昇時,讓前述吸引 裝置動作’以從中空狀的活塞78A、78B的前端對內包材5 的空間5A、5B內的空氣進行吸引。以與該吸引動作連動的 方式,使包覆切斷裝置21動作,而從內包有固態物A、B之 三層構造的棒狀麵團19製造出沿水平方向內包2個固態物A 、B之包覆食品23。這時,分別收容有固態物A、B的袋狀 空間5A、5B內被減壓,因此前述空間5A、5B會縮小。因 此,對於各個固態物A、B,其周圍的內包材5會移動而形 成密合,因此可抑制形成在固態物A、B周圍的間隙,而能 防止在烘烤等的熱處理步驟時包覆食品發生破裂(內部空 氣因加熱而膨脹,導致包覆食品破裂)。此外,在本說明 中,前述管構件41A、41B的下端的位置是與前述外皮材用 嘴47的下端的位置一致,但並不限於此,管構件41A、41B 的下端位置比前述外皮材用嘴47的下端位置位在更下方亦 可。藉由採用這種配置,在進行吸引時,能將接近前述固 態物A、B的區域之棒狀麵團19朝前述空間5A、5B側縮小 201021713 ,而使周圍內包材5密合於固態物A、B的效果提昇。在此 說明的例子,是使活塞78A、78B形成中空狀且從前端(下 端)吸引空氣,但在活塞78 A、78B和導入導件37的通路( 貫通孔39A及管構件41A、貫通孔39B及管構件41B )之間 設置空氣吸引用的空間,而從活塞78A、78B的下端吸引空 氣亦可。 詳而言之,前述棒狀麵團19是被連續吐出。該棒狀麵 0 團19的底部,是被從下方往上昇的輸送裝置25支承,然後 ,輸送裝置25是以與所吐出的棒狀麵團19的吐出速度大致 相同的速度下降。此外,包覆切斷裝置21,在從上昇位置 以比前述棒狀麵團19的吐出速度稍快的速度下降的狀態下 ,將前述棒狀麵團19切斷。因此,是在包覆切斷裝置21的 下面和輸送裝置25的上面之間將棒狀麵團19夾住而切斷成 包覆食品23。這時,包覆食品23內的固態物a及固態物B, 由於內包材5被推入固態物a和固態物B之間而使彼此互相 φ 分離。本申請人發現,作爲抑制包覆食品23內的固態物A 及固態物B互相分離的手段,是將內包材用嘴45的吐出口 45 A及外皮材用嘴47的吐出口 4 7 A形成長圓形或橢圓形。 在此說明’前述棒狀麵團19藉由前述包覆切斷裝置21 所具備的6片遮擋體21A進行包覆切斷的步驟。被6片遮擋 體21A包圍而形成之正多角形(正六角形)的開口 H 口徑 逐漸縮小。此外,從外皮材用嘴47 (疊合嘴13)吐出之棒 狀麵團19’是以水平截面呈長圓形的形狀被吐出,而沿前 述開口 Η內流下。首先,前述棒狀麵團19,在棒狀麵團19 -17- 201021713 內的固態物A及固態物B的上方位置,從棒狀麵團19的長圓 形的長軸DL側受到前述遮擋體21A的擠壓作用(參照第9 (la)圖)。接著,前述開口 Η的口徑縮小。這時,受到 來自遮擋體21Α的擠壓作用,外皮材9及內包材5會沿著前 述長軸DL朝中心方向流動。此外,由於棒狀麵團19的長圓 形的短軸DS側未接觸遮擋體21Α,外皮材9及內包材5也會 沿著前述短軸DS而朝外側流動。而且,隨著內包材5朝中 心方向流動,固態物Α與固態物Β會暫時朝中心側移動而互 @ 相接近。 接著,前述開口 Η的口徑進一步縮小,棒狀麵團19的 短軸DS側也受到前述遮擋體21 Α的擠壓作用(參照第9 ( lb)圖)。前述棒狀麵團19’被6片遮擋體21A大致均等地 擠壓。接著,前述開口 Η閉鎖’而從前述棒狀麵團19包覆 切斷成包覆食品23(參照第9(1 c)圖)。這時,藉由前 述開口 Η的口徑縮小,而使前述外皮材9及內包材5朝中心 流動。此外,前述內包材5也會朝前述遮擋體21Α的下方流 〇 動。因此,前述內包材5會進入前述固態物Α和固態物Β之 間’而使前述固態物A和固態物B分離。然而’在前述包覆 食品23內,固態物A、B彼此的間隔與配置於前述棒狀麵團 19內部之固態物A、B彼此的間隔不會發生大幅的改變(參 照第7圖、第9(la) ~(1<〇圖)。此外,專利文獻1所記 載之2個1組的固態物,由於在棒狀麵團內是上下方向重疊 成密合狀態,在接下來的步驟之模壓成型時’會發生固態 物彼此的間隔無法一定的問題。然而’依據本發明的第1 -18- 201021713 實施形態,由於能將2個固態物A、B以在水平方向分離的 狀態供應至棒狀麵團19內,而能製造出固態物a、b彼此的 間隔穩定的包覆食品23。 以上是大致說明依據本發明的第1實施形態之包覆切 斷裝置1,但在申請專利範圍內可進行各種的改變。例如 使用第9(2a) (2b) (2c)圖來作說明。在本例中,從 外皮材用嘴47吐出的棒狀麵團91,是以水平截面呈圓形的 φ 形狀被吐出’且將2個固態物以分離的狀態供應至棒狀麵 團91的內部。棒狀麵團91藉由包覆切斷裝置所具備的6片 遮擋體21A進行包覆切斷,而製造出2個固態物在水平方向 互相分離之包覆食品93。 以上雖是說明構成棒狀麵團19、91的食品材料是由內 包材5及外皮材9所構成的雙層構造,但只要能包入複數個 固態物即可,也能是由單層或三層以上的食品材料所構成 的棒狀麵團。 Φ 此外,在上述說明中,固態物A及固態物B是分別以一 塊固態的形式來作說明,但例如也能將複數個甘納豆所構 成的固態物群作成一團而收容於收容孔65,以在包覆食品 23內的複數個部位收容複數個固態物群。在此情況也是, 複數個固態物群在包覆食品23的內部沿水平方向配置。此 外’也能有效地進行利用吸引裝置的吸引。 此外,一次供應給棒狀麵團19、91的固態物(固態物 群)並不限於2個,例如是3個也可以。在此情況,如第8 (b)圖所示’內包材用嘴45的吐出口 45J及外皮材用嘴47 -19- 201021713 的吐出口 47J的形狀,是呈大致三角形(正三角形的角呈 圓弧狀變形的形狀)且方向一致。此外,3根管構件41A、 41B、41C,是在前述吐出口 45J的內側,以與前述吐出口 45 J的中心隔著相同距離且沿著從該中心往各角部的方向 (與前述三角形的各角的方向同義。在此’該方向視爲長 軸DL的方向)進行配置。對於該吐出口 47J,例如讓3片遮 擋體21 B所形成的開口 J如第8(b)圖所示成爲方向一致時 ,在包覆切斷歩驟的初期,棒狀麵團的全周不會被均一地 擠壓,而能使固態物朝中心側移動。接著,被遮擋體21B 擠壓的內包材可沿著短軸DS的方向往包覆食品的外周側移 動,而能以固態物在包覆食品之外周部不發生偏置的方式 進行包覆切斷。短軸DS是配置在:將前述3根長軸DL彼此 所形成的角二等分的方向。此外,在製造內包有4個等的 固態物之包覆食品的情況也是同樣的。 接著,使用第10圖至第14圖來說明本發明的第2實施 形態之包覆切斷裝置1。與第1實施形態的構造發揮相同功 效的構成要素,是賦予相同的符號而省略重複的說明。第 2實施形態之固態物供應裝置57的旋轉盤64,是在圓周Pi 等間隔地設置1 5個收容孔92。該收容孔92,從俯視觀察, 是2個相同的圓孔(第1收容孔92A及第2收容孔92B)形成 局部重疊的形狀,亦即呈所謂8字外形的形狀(在此稱爲 局部疊合圓)。此外,第1收容孔92 A及第2收容孔92B的圓 心’是配置成與旋轉盤64的中心隔著等距離。此外,托盤 63的開口 63 B是形成與前述收容孔92對應的形狀。 201021713 再者,在托盤63的開口 63B和座板59B之間,配置可沿 水平方向往復移動的遮擋板87。該遮擋板87,在前述旋轉 盤64旋轉時,是位於前述開口 63 B的下方而制止固態物A及 固態物B落下,在前述旋轉盤64停止於既定位置時,是朝 內包材用料斗7或外皮材用料斗11側(第10圖的上側,第 12圖的右側)水平移動。而且,藉由在第1收容孔92A及第 2收容孔92B分別收容固態物A及固態物B,且讓前述旋轉 φ 盤64以每次24度的方式間歇地朝一方向(第10圖的逆時針 方向)旋轉,以同時將固態物A及固態物B間歇地供應至疊 合嘴13內。 在疊合嘴13之前述內筒35的內側,設置導入導件94。 該導入導件94具有凸緣構件95。形成於該凸緣構件95的凸 緣部95C的下面之突條部95D嵌合於前述內筒35的凹狀狹縫 3 5B,藉此定位成:使貫通孔97和停止於其上方之前述旋 轉盤64的收容孔92形成同心狀。 © 在該凸緣構件95嵌合管構件96。管構件96,從俯視觀 察是形成有:與前述收容孔92同樣的呈8字外形(局部疊 合圓)之貫通孔97 (通路)。該貫通孔97,是由第1貫通 孔97A及第2貫通孔97B所構成,相對於凸緣構件95的中心 線是形成對稱的。該貫通孔97的寬度,亦即俯視之長徑DL 方向的長度,是比形成各貫通孔97A、97B的圓的直徑更長 ’且比圓的直徑的2倍短;在本例是圓直徑的丨.9倍。此外 ’在該貫通孔97’形成有相對向的內側突出部97c (第1貫 通孔97A及第2貫通孔97B的圓弧交叉的部分)。由於相對 -21 - 201021713 向的內側突出部97C的間隔比形成各貫通孔97A、97B的圓 的直徑更短,從旋轉盤64供應的固態物A、B,不致侵入相 對向的貫通孔97A、97B,而在互相接近的位置沿貫通孔內 落下。 管構件96的外形是形成順沿(相似)貫通孔97,從俯 視觀察,在短徑DS上形成相對向的凹部97D (參照第14圖 )。此外,在前述管構件96的下端部,在貫通孔97的長徑 DL上的兩端對稱地形成有傾斜部97TA及傾斜部97TB (參 照第11圖)。再者,傾斜部97TA及傾斜部97TB的上端是 位於比前述內包材用嘴45的吐出口 45C更上方,其下端( 亦即管構件96的下端)是位於比前述吐出口 45C更下方( 參照第11圖)。而且,前述內包材用嘴45的吐出口 45C及 前述外皮材用嘴47的吐出口 47C是形成圓形。 在固態物供應裝置57的推入裝置71設置2根桿件77A、 77B。在前述桿件77A及桿件77B的下端部,螺合用來連結 其等的活塞構件98。在該活塞構件98的下部,配設有分別 與桿件77A、77B形成同心的活塞98A、98B。此外,在活 塞98 A及活塞98B的下面分別形成有:互相對向且往下方擴 大的傾斜面98TA及傾斜面98TB。該活塞構件98被設置成 :可插通於停止旋轉後的前述旋轉盤64的收容孔92及裝設 於疊合嘴13之導入導件94的貫通孔97。再者,前述桿件 77A、77B及前述活塞98A、98B是形成中空狀,前述桿件 77A、77B的上端是連通於未圖示的吸引裝置。 在此說明本發明的第2實施形態之包覆切斷.的步驟。 -22- 201021713 從疊合嘴13的下方吐出棒狀麵團19。該棒狀麵團19,是用 外皮材9包覆內包材5而形成雙層構造。內包材5,是通過 內包材用嘴45的內周面和導入導件94的管構件96的外周面 之間而從該內包材用嘴45的吐出口 45C吐出。這時,由於 內包材5是沿著前述管構件96的外形流下,在內包材5的內 部,空間6A和空間6B會一體化而形成袋狀空間6。該袋狀 空間6,是形成水平截面呈8字外形的局部叠合圓的形狀。 φ 此外,從管構件96的下端往下流的內包材5,隨著外 皮材用嘴47的內徑越往下越小,會朝中心方向流動而縮徑 ,且使其內部的前述袋狀空間6變小。再者,由於在管構 件96的下端設置傾斜部97TA、97TB,比起其他下端部分 ,內包材5會先從管構件96的長徑DL側往前述袋狀空間6側 流動,而使前述袋狀空間6縮小。 固態物供應裝置57的旋轉盤64,朝箭頭T方向旋轉24 度後再度停止。接著,若遮擋板87從旋轉盤64的下方往外 〇 側移動,固態物A、B會同時從旋轉盤64的第1收容孔92A 、第2收容孔92B落下,而個別供應至前述內包材5的空間 6A、6B。再者’在前述旋轉盤6 4停止旋轉的同時,驅動前 述推入裝置71的無桿氣缸,使停止於上昇位置之活塞構件 98的第1活塞98A、第2活塞98B分別沿收容孔92A、92B、 導入導件94所具備的管構件96的第1貫通孔97A、第2貫通 孔978的內部往下降。而且,活塞98八的傾斜面98丁入及活 塞98B的傾斜面98TB將前述固態物A及固態物B往中心朝斜 下方擠壓,使固態物A及固態物B移動而互相接近且與形成 -23- 201021713 前述袋狀空間底部之內包材5密合,並在前述固態物A及固 態物B之間介入內包材5,而以不互相密合的方式沿水平方 向配置。 活塞98A的傾斜面98TA及活塞98B的傾斜面98TB,是 將前述固態物A及固態物B往中心擠壓的擠壓面,其形狀並 不限於平面,亦可爲曲面和彎曲面等,只要是能將固態物 擠壓到所要位置的構造即可。 下降至降下停止位置後的前述活塞構件98,再度上昇 。在前述活塞構件98上昇的前後或上昇時,讓前述吸引裝 置動作,以從中空狀的第1活塞98 A及第2活塞98B的前端吸 引內包材5的袋狀空間6內的空氣,並讓前述包覆切斷動作 21動作,以從前述棒狀麵團10製造出沿水平方向內包有固 態物A、B之包覆食品23。 與第1實施形態的包覆切斷步驟同樣的,在包覆切斷 裝置21的下面和輸送裝置25的上面之間,將內包有固態物 A及固態物B的棒狀麵團19夾住並切斷成包覆食品23。詳而 言之,從外皮材用嘴47吐出的棒狀麵團19,沿前述開口 Η 內往下流,隨著前述開口 Η在棒狀麵團19內的固態物Α及 固態物B的上方位置進行縮徑,受到來自6片遮擋體21A之 均等的擠壓作用。這時,藉由遮擋體21 A的擠壓作用,外 皮材9及內包材5會朝中心方向及前述遮擋體21A的上下方 向(第13圖的紙面的上下方向)流動。因此,前述內包材 5將前述袋狀空間6縮小並進入接近的固態物a、固態物B之 間,而使固態物A、固態物B逐漸分離。接著,前述開口 η -24- 201021713 會進一步縮小口徑,而從棒狀麵團19包覆切斷成包覆食品 23。在此期間,前述內包材5會繼續進入固態物A、固態物 B之間,而使固態物A、固態物B進一步分離。然後’藉由 將該包覆食品23實施模壓成型’而使最終製品內的固態物 A、固態物B彼此隔著適當的間隔沿著水平方向配置。 此外,與前述包覆切斷裝置21的切斷動作形成連動, 在前述活塞構件98上昇的前後或上昇時,讓前述吸引裝置 φ 動作,以從中空狀的第1活塞98A及第2活塞98B的前端吸引 內包材5的袋狀空間6的空氣,藉此將收容有固態物A、B的 袋狀空間6內減壓而使其縮小。因此,固態物A、B周圍的 內包材5會移動而密合於各固態物A、B,而能抑制在各固 態物A、B的周圍和內包材5之間形成的間隙。 在本發明的第2實施形態之包覆切斷裝置1,關於前述 內包材用嘴45的吐出口 45C及前述外皮材用嘴47的吐出口 47C的形狀雖是說明圓形的例子,但與本發明的第1實施形 Φ 態同樣的形成長圓形或橢圓形亦可,又對應於其形狀來配 置遮擋體21A亦可。 根據上述說明可理解到,藉由使複數個固態物沿個別 的通路(管構件41A及41B、第1貫通孔97A及第2貫通孔 9 7 B )內個別落下,可在棒狀麵團內將複數個固態物沿水 平方向配置,且以不互相密合的方式進行供應。 置密 裝料 弓材 吸品 於食 通讓 連可 塞, 活氣 的空 置弓 裝吸 應間 供空 物狀 態袋 固的 使內 由團 藉麵。 ’狀物 外棒態 此從固 並於 ’ 合 -25- 201021713 【圖式簡單說明】 第1圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的前視圖。 第2圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部的側視圖,其一部分是以截面顯示。 第3圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部之俯視圖。 第4圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部,是第3圖的X-X線的截面圖。 第5圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部,是第3圖的Y-Y線的截面圖。 第6圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部,是用來說明第5圖的各部的組裝順序的 截面圖。 第7圖係槪略顯示本發明的第1實施形態之包覆食品製 造裝置1的主要部的前視圖,其一部分是以截面顯示。 第8(a) (b)圖係槪略顯示本發明的第1實施形態之 包覆食品製造裝置1的主要部的說明圖。 第9 (la) ~(2c)圖係槪略顯示本發明的第1實施形 態之包覆食品製造裝置1的主要部的說明圖。 第1 〇圖係槪略顯示本發明的第2實施形態之包覆食品 製造裝置1的主要部之俯視圖。 第11圖係槪略顯示本發明的第2實施形態之包覆食品 -26- 201021713 製造裝置1的主要部’是第1 0圖的w-w線的截面圖。 第12圖係槪略顯示本發明的第2實施形態之包覆食品 製造裝置1的主要部,是第10圖的V-V線的截面圖。 第13圖係槪略顯示本發明的第2實施形態之包覆食品 製造裝置1的主要部的前視圖,其一部分是以截面顯示。 第I4圖係槪略顯示本發明的第2實施形態之包覆食品 製造裝置1的主要部,是第10圖的z-z線的截面圖。 ❹ 【主要元件符號說明】 1 :包覆食品製造裝置 2:包餡機 3 :架台 5 :內包材 5A' 5B、6:袋狀空間 6A、6B :空間 φ 7:內包材用料斗 8、12 :螺桿 9 :外皮材 10、14 :葉輪泵 1 1 :外皮材用料斗 13 :疊合嘴 15:內包材供應裝置 17:外皮材供應裝置 19、91 :棒狀麵團 -27- 201021713 2 1 :包覆切斷裝置 21A、21B :遮擋體 23、93 :包覆食品 25 :輸送裝置 25A :輸送帶 25B :驅動滑輪 26 :上下動板 27 :攪拌旋轉構件 27A :攪拌構件 3 1 :上部殼體 32 :外筒 32A、32B :連接口 32C :筒部 3 3 :下部殼體 3 5 :內筒 35A、35B :凹狀狹縫 3 7 :導入導件 39、79、95:凸緣構件201021713. EMBODIMENT OF THE INVENTION The present invention relates to the manufacture of a package, such as a fruit such as a strawberry or a chestnut, or a solid product such as a boiled egg, to a dough such as a cake or a hamburger. A manufacturing device and a manufacturing method for covering food. Specifically, it relates to a manufacturing apparatus and a manufacturing method for manufacturing two or more solid materials. [Prior Art] Traditional Chinese snacks have a moon cake (called double egg yolk moon cake) containing two salted duck egg yolks. Salted duck egg yolk is a solid substance that is salted with duck egg yolk. Double egg yolk mooncakes are typically molded into disc shapes or cuboids (bottom squares). Preferably, the moon cake is coated with two salted duck egg yolks which are equally separated from the center of the moon cake to the left and right (radial direction). Patent Document 1 describes a manufacturing apparatus (packing machine) for producing a coated φ food containing two solid materials. The filling machine is provided with an outer cylinder, an inner cylinder and a center cylinder which are concentric nozzles formed in a concentric shape. A solid material supply device is provided at the upper portion of the stacking nozzle. A coating cutting device is provided below the stacking nozzle. Further, a belt conveyor as a conveying device is provided below the wrapping and cutting device. Further, on the downstream side of the conveying device, there is provided a molding machine that performs a press molding on the coated food. The solid-state supply device is provided with a rotatable disk which is rotatably formed with a receiving hole (accommodating one set of two solid objects) through a predetermined interval. From the solid matter supply device, two solid materials which are one set are intermittently supplied -5 - 201021713 to the center cylinder of the stacking nozzle. Then, a bar-shaped food having a three-layer structure (constructed from a solid material, an inner material covering the solid material, and an outer skin material covering the inner material) is discharged from the superposed mouth. Then, the coated food was cut from the rod-shaped food into a coated food containing two solid materials by a coating and cutting device. At this time, the two solid materials are closely adhered in such a manner that they overlap in the upper and lower directions of the inside of the coated food. Then, the direction of the coated food is manually switched, and the vertical direction is oriented in the conveyance direction (horizontal direction). Thereafter, the coated food was subjected to compression molding by the aforementioned molding machine. At this time, it is necessary to adjust the directionality of the coated food by manual work or the like, and therefore it is desired to improve the manufacturing efficiency. Further, since the two solid matter ' in the coated food product is subjected to extrusion deformation by a mold in a state in which the solid materials are in close contact with each other, the solid materials may not be separated from each other. Further, even in the case where the solid materials are separable from each other, since the degree of adhesion of the solid objects to each other is not constant, there is a problem that the intervals of the solid objects are not stable. Further, since a void is formed between the two solid materials, the coated food may be cracked during baking (the internal air expands due to heating, causing the coated food to rupture). In particular, in the case where the coated food is a double egg yolk moon cake, there is a problem that the commercial price is significantly lowered. Therefore, the conventional double egg yolk moon cake can only be manufactured by hand, and it is expected to provide a manufacturing apparatus and a manufacturing method which can improve production efficiency. [Patent Document 1] Chinese Utility Model Patent No. 268 63 46 [Description of the Invention] When a coated food containing two or more solid materials (or a solid group of two or more groups) is contained, there is a solid matter Problems that cannot be separated from each other -6 - 201021713 The problem that the solid objects are unstable from each other. Further, since voids are formed around the solid matter, the problem of cracking of the coated food may occur during heat treatment. The present invention provides a manufacturing apparatus for a solid-coated food containing a plurality of solid materials, which is provided with the above-mentioned problems, and is characterized in that it comprises a stuffing machine having a stacked mouth and a simultaneous supply of the filling machine The solid matter supply device of the plurality of solid materials; the stacking nozzle includes a pipe member having a passage for individually lowering a plurality of Φ solid objects, and a nozzle member surrounding the pipe member. Further, the apparatus for manufacturing a solid-coated food product is characterized in that the shape of the discharge port of the nozzle member has a long axis along the direction in which the passage of the pipe member is disposed. Further, the apparatus for manufacturing a solid-coated food product includes a piston that can move up and down in the pipe member, and a lower surface of the piston that presses the plurality of solid materials toward a center thereof Further, the apparatus for manufacturing a solid-coated food product according to the present invention includes a piston that can move up and down in the pipe member, and communicates the piston with a suction device that sucks air from a tip end of the piston. According to the present invention, when the coated food is coated and cut from the rod-shaped food containing a plurality of solid materials, the solid matter can be disposed in the rod-shaped food in a horizontal direction so as not to be in close contact with each other. . In addition, the solid matter can be brought into close contact with the food material covering it. This application is based on Japanese Patent Application No. 201021713 2008-294984, filed on Nov. 18, 2008, and Japanese Patent Application No. 2000-113173, filed on May 8, 2009, the content of The content of the part. Further, the present invention will be more completely understood from the following detailed description. However, the Detailed Description and the Detailed Description are merely illustrative of the preferred embodiments of the invention. Various changes and modifications made in light of the details of this detailed description will be apparent to those skilled in the art. The Applicant does not intend to dedicate any of the described embodiments to the public. In the disclosed changes and alternatives, even if it is not included in the scope of the patent application, it is part of the invention that constitutes the theory of equalization. The use of nouns and the same pronouns in the description of this specification and the scope of the patent application In the absence of special instructions, or in the absence of a clear understanding of the context, it should be interpreted as including both singular and plural. The use of the exemplified or exemplified terms (e.g., "etc.") is used in the specification, and is not intended to limit the scope of the present invention. [Embodiment] The coated food manufacturing apparatus 1 according to the first embodiment of the present invention will be described with reference to Figs. 1 to 3 . The coated food manufacturing apparatus 1 is provided with a stuffing machine 2. The filling machine 2 is provided with a stand 3. On the upper surface of the gantry 3, a hopper 7 for containing the inner packaging material 5 (food material) and a hopper 11 for outer skin material for accommodating the outer skin material 9 (-8 - 201021713 food material) are provided. The inner packaging material supply device 15 is disposed on the lower side of the hopper 7 for the inner packaging material. The screw 8 and the impeller pump 1 are collected in the inner packaging material supply device 15. Further, the outer skin material supply device 17 is disposed on the lower side of the outer skin material hopper 11. The screw 12 and the impeller pump 14 are housed in the outer skin supply device 17. Further, the stacking nozzle 13 is disposed between the inner package supply device 15 and the outer skin supply device 17. The cover cutting device 21 is disposed below the stacking nozzle 13. In addition to the φ, the stacking nozzle 13 can discharge a rod-shaped dough 19 having a three-layer structure; the rod-shaped dough 19 is formed by coating the outer sides of the two solid materials A and B with the inner wrapping material 5 The outer side of the packaging material 5 is laminated with the outer skin material 9. In the coating and cutting device 21, the coated food 23 in which the solid A and the solid B are contained is covered and cut from the rod-shaped dough 19. The conveying device 25 is provided below the coating and cutting device 21. The conveying device 25 has an endless flat belt body. This flat belt body is a conveyor belt 25A for conveying the coated food 23, and is wound around the drive pulley 25B φ to operate intermittently. Further, the vertical movement plate 26 is provided on the inner side of the conveyor belt 25A so as to be movable up and down at a position below the overlap nozzle 13. As the vertical movement plate 26 moves up and down, a part of the conveyance surface of the conveyor belt 25A moves up and down. Here, the conveying device 25 is also referred to as moving up and down. Further, the above-described inner packaging material supply device 15, outer skin material supply device 17, cover cutting device 21, and conveying device 25' may be of a known configuration, and thus detailed description of the structure thereof will be omitted. Next, description will be made with reference to Figs. 4 to 9. The aforementioned overlapping nozzle 13 has an upper casing 31 and a lower casing 33 of -9 - 201021713. The upper casing 31 is provided with an outer cylinder 32 and an inner cylinder 35. The side portions of the outer cylinder 32 have a connection port 32A and a connection port 32B, respectively (refer to Fig. 7). The connection port 32A communicates with the aforementioned inner package supply device 15. Further, the connection port 32B communicates with the aforementioned outer skin material supply device 17. Inside the outer cylinder 32, an inner cylinder 35 concentric with the tubular portion 32C of the outer cylinder 32 is provided. The inner cylinder 35 is hollow, and a side opening of the tubular portion thereof communicates with the aforementioned connection port 32A. The inner cylinder 35 is formed to allow the inner packaging material 5 to pass therethrough. An annular space R1 is formed between the inner circumferential surface of the cylindrical portion 32C of the outer cylinder 32 and the outer circumferential surface of the inner cylinder 35. The annular space R1 communicates with the communication port 32B. Therefore, the inside of the outer cylinder 32 is formed to allow the outer casing 9 to pass therethrough, and the introduction guide 37 is provided inside the inner cylinder 35. The introduction guide 37 is a member for guiding the solid matter to a position below the overlapping nozzle 13. The introduction guide 37 has a flange member 39. The flange member 39' is formed with two through holes 39A, 39B symmetrically with respect to the center line of the flange member 39. The introduction guide 37 has two tube members 41A and 41B having the same shape. Each of the upper end portions of the Q tube members 41A and 41B is fitted into the through holes 39A and 39B, respectively, and is screwed to an appropriate position. Further, a pin member 43 for positioning is attached to the upper surface of the flange member 39. In the present embodiment, the arrangement direction of the pin member 43 is orthogonal to the direction in which the through holes 39A and 39B are disposed. Further, the positioning ridge portion 39D for positioning is formed on the lower surface of the flange portion 39C of the flange member 39. The ridge portion 39D is disposed in the same direction as the center line of the flange member 39 in the vertical direction in the arrangement direction of the pin member 43 @-10-201021713. Further, a concave slit 35A fitted to the ridge portion 39D is formed at the upper end portion of the inner cylinder 35. Further, the inner bag 45 is screwed to the lower end portion of the inner tube 35. The flange member 39 is fitted to the inner side of the inner cylinder 35 from above, and is fixed to the inner cylinder 35 by a nut member 83 in a state where the flange portion 39C is placed on the inner cylinder 35. The lower casing 33 has an outer skin material nozzle 47 and a casing 49. The outer skin material nozzle 47 is fitted from below the outer casing 49, and is fixed by φ by the nut member 51. By attaching the outer casing 49 to the lower surface of the outer cylinder 32, the outer material material nozzle 47 is disposed to surround the inner packaging material nozzle 45. Therefore, an annular space R2 is formed between the outer circumferential surface of the inner packaging material nozzle 45 and the inner circumferential surface of the outer material material nozzle 47, and the annular space R2 communicates with the annular space R1 formed in the upper casing 31. Thereby, an annular space R through which the outer skin material 9 passes is formed inside the overlapping nozzle 13. Between the upper casing 31 and the lower casing 33, a stirring rotating member 27 (connected to a drive unit (not shown) U) is rotatably provided. The agitation rotating member 27 is provided with a stirring member 27A that is disposed to be rotatable in the annular space R. The agitating rotary member 27 is a sheath 9 for agitating through the annular space R. As shown in Fig. 8(a), the inner peripheral surface of the inner bag 45 has a size that allows the two pipe members 41A and 41B to pass through. Further, the discharge port 45A of the above-described inner package material nozzle 45 is formed in an oblong shape. Further, the discharge port 47 of the outer skin material nozzle 47 is also formed in an oblong shape. Further, the long axis of the discharge port 45A and the long axis of the discharge port 47A are respectively B IX 4 ' A 4 pipe members disposed along the forward direction of the horizontal water raft. 2 -11 - 201021713 The shape of the discharge port 45A and the discharge port 47A may be elliptical. The gap between the discharge port 45A and the discharge port 47A is substantially the same throughout the entire circumference. Next, the positioning mechanism for the tubular members 41A and 41B will be described for the inner packaging material nozzle 45 and the outer material material nozzle 47. The two positioning pins 53 are screwed to the symmetrical position with respect to the center line in the vertical direction of the inner package nozzle 45 on the side surface of the inner package nozzle 45. In addition, a concave fitting groove 47B into which the pin 53 is fitted is formed at two locations on the inner peripheral surface of the upper portion of the outer skin material nozzle 47 (see Fig. 5). Further, the positioning pin 55 is pressed into the upper outer peripheral surface of the outer skin material nozzle 47. In the present embodiment, the pin 55 is mounted in a horizontal direction orthogonal to the direction in which the two fitting grooves 47B are formed (horizontal direction). Further, on the inner circumferential surface of the outer casing 49, a fitting groove 49B having a concave shape into which the pin 55 of the outer skin material nozzle 47 is fitted is formed. The solid material supply device 57 is detachably placed on the upper portion of the stacking nozzle 13. The solid material supply device 57 is provided with a seat portion 59. In the solid-state supply device 57, the base end portion 59A (the left side of Fig. 2) of the seat portion 59 is attached to the stuffing machine 2 by a fastening screw 61. On the upper surface of the seat plate 5 9B of the seat portion 59, a tray-shaped tray 63 is detachably attached by a screw. An opening 63A above the aforementioned overlapping nozzle 13 is formed on the bottom surface of the tray 63. Further, the rotary disk 65 is disposed inside the tray 63. Provided below the seat plate 5 9B is a driving device for intermittently rotating and driving the rotary disk 65. As the drive device, a known mechanism can be employed. For example, an electric motor such as a servo motor or a ratchet mechanism can be used. Further, the rotary disk 65 is detachably attached to the rotary shaft 69 of the front drive device by the fastening screw 67. The rotary disk 65' is formed with 24 receiving holes 65 A at equal intervals on the circumference P. Further, the rotating disk 65 is formed with 24 receiving holes 65B at equal intervals on the circumference Q having a smaller diameter than the circumference P. In other words, the rotating disk 65 has 24 sets of receiving holes in which a certain receiving hole 65A and one of the receiving holes 65B adjacent to the receiving hole 65A are in a group. Further, the rotary table 65' is intermittently rotated in one direction (counterclockwise direction of Fig. 3) by φ of 15 degrees per rotation by the rotation of the rotary shaft 69. The solid material A and the solid material B are accommodated in the accommodation holes 65A and 65B, and the rotary disk 65 is intermittently rotated to intermittently supply the solid material A and the solid material B into the stacking nozzle 13. Further, in the solid matter supply device 57, the pusher device 71 is provided above the rotary disk 65 and the stacking nozzle 13. The push-in device 71 is for pushing the solid objects A, B supplied into the above-mentioned stacking nozzle 13 to a position below the stacking nozzle 13. The push-in device 71 has a bracket 73. The bracket 73, φ is provided between the tray 63 and the fastening screw 61, and is attached to the seat portion 59 in the longitudinal direction in the longitudinal direction. Further, the rodless cylinder 75 as a direct acting actuator is fixed to one side surface of the bracket 73. The rodless cylinder 75 is arranged such that the moving direction of the slider 75A is along the vertical direction. Further, on the slider 75 A, two bars 77A, 77B are mounted by the holder 75B. The two rod members 77A, 77B are arranged to be parallel to each other, and the longitudinal direction thereof is along the vertical direction. Pistons 78A, 78B are screwed to the respective lower ends of the rod 77A and the rod 77B, respectively. The pistons 78A and 78B are disposed so as to be respectively inserted into the receiving hole 65A and the receiving hole 65B of the front plate 13-201021713 of the rotating disk 65 after the rotation is stopped. Further, the rods 77A and 77B and the pistons 78A and 78B are formed in a hollow shape, and the upper end portions of the rods 77A and 77B are connected to a suction device (not shown). Next, the positioning mechanism of the aforementioned solid matter supply device 57 and the aforementioned stacking nozzle 13 will be explained. A flange member 79 is mounted under the seat plate 59B of the aforementioned solid material supply device 57. The flange member 79 has two through holes 79A and 79B. Each of the through holes 79A and 79B is disposed so as to correspond to each of the accommodation holes 65A and 65B of the rotary disk 65 after the rotation is stopped. Further, a fitting recess 7 9C is formed below the flange member 79. A fitting hole 79H for positioning is formed on the bottom surface of the fitting recess 79C. The fitting recess 79C is fitted to the upper end portion of the flange member 39 of the introduction guide 37 of the above-described overlap nozzle 13. At this time, the fitting hole 7.9H is fitted to the pin member 43 of the above-described superposition nozzle 13 to be positioned. Thus, the stacking nozzle and the solid matter supply device constitute a positioning mechanism such that the respective passages are combined in the same direction so that the solid matter can pass through the solid matter supply device and the aforementioned overlap nozzle. The rod members 77A' to 77B of the pusher 71, the accommodation holes 65A and 65B of the rotary disk 65, and the tube members 41A and 41B of the stacking nozzle 13 are arranged substantially concentrically in plan view. Further, the directivity of the discharge port 45A of the inner package material nozzle 45 and the discharge port 47A of the outer material material nozzle 47 can be made to match the directivity of each of the above members. In other words, the long axis of the discharge port 45 A of the inner package material nozzle 45 and the discharge port 47 7A of the outer material material nozzle 47 can be aligned in the horizontal direction with the arrangement direction of the pipe members 41A and 41B. Further, when each member is assembled to the body of the coated food manufacturing apparatus 1, it is easy to perform alignment of the members. Further, the anti-vibration plate 81 is movably provided in the vertical direction inside the inner cylinder 35. An oblong insertion hole 81A is formed inside the vibration-proof plate 81. The tube members 41A and 41B are inserted into the insertion hole 81A. The anti-vibration plate 81 functions to prevent the tube members 41A and 41B from vibrating in the radial direction when the pistons 78A and 78B move up and down inside the tube members 41A and 41B, respectively. Here, the step of coating and cutting according to the first embodiment of the present invention will be described. φ The coated food here refers to double egg yolk moon cake, the outer skin material uses moon cake dough, the inner packaging material uses stuffing, and the solid material uses salted duck egg yolk. The state in which the inner packaging material 5 and the outer skin material 9 are discharged from the lower side of the stacking nozzle 13 will be described. The rod-shaped dough 19 is discharged from the discharge port 47 A of the outer skin material nozzle 47. The rod-shaped dough 19 is a two-layer structure in which the inner wrapping material 5 is covered with the outer skin material 9. The inner packaging material 5 is discharged from the discharge port 45 A of the inner packaging material nozzle 45 by the inner circumferential surface of the inner packaging material nozzle 45 and the outer circumferential surfaces of the two tubular members 41A and 41B of the introduction guide 37. . At this time, in the inside of the inner packaging material 5 which is spouted in a bar shape, 2 φ-shaped cylindrical spaces 5A and 5B having a bottom portion are formed. At this time, the rotary disk 65 of the solid material supply device 57 is rotated 15 degrees in the direction of the arrow T and then stopped again. Thus, the solid objects A, B are simultaneously dropped from the receiving holes 65 A, 65B of the rotary disk 65, and are individually supplied to the spaces 5A, 5B of the inner packaging material 5. Further, while the rotary disk 65 is stopped, the rodless cylinder of the push-in device 71 is driven, and the respective pistons 78A and 78B stopped at the rising position are guided along the receiving holes 65A and 65B and the guides 37 (through holes). The inside of the 39A and the pipe member 41A, the through hole 39B, and the pipe member 41B) are lowered. At this time, in the case where the solid matter stays in the passage, the pistons -15 - 201021713 78A, 78B can push the solid objects A, b to the lowered position, and can stably supply the solid matter a to the aforementioned spaces 5A, 5B in the bag shape. , B. Further, since the pistons 78A and 78B push the solid objects a and B to the bottom portions of the pocket-shaped spaces 5A and 5B, the lower portions of the solid objects a and b can be adhered to the inner packaging member 5. Further, since the inner packaging material 5 is interposed between the two solid materials a and B, the solid objects a and B are not in contact with each other in the rod-shaped dough 19, but are disposed to be separated from each other in the horizontal direction. The aforementioned pistons 78A, 78B after descending to the lowered position are again raised. The suction device is operated to move the air in the spaces 5A, 5B of the inner packaging material 5 from the front ends of the hollow pistons 78A, 78B before or after the rise of the pistons 78A, 78B. The cover cutting device 21 is operated in conjunction with the suction operation, and the two solid materials A are wrapped in the horizontal direction from the rod-shaped dough 19 having the three-layer structure of the solid materials A and B. B coated food 23 . At this time, since the inside of the pocket-shaped spaces 5A and 5B in which the solid objects A and B are accommodated are decompressed, the spaces 5A and 5B are reduced. Therefore, for each of the solid materials A and B, the surrounding inner covering material 5 moves to form a close contact, so that the gap formed around the solid objects A and B can be suppressed, and the heat treatment step of baking or the like can be prevented. The covered food ruptures (the internal air expands due to heating, causing the coated food to rupture). In the present description, the positions of the lower ends of the pipe members 41A and 41B coincide with the positions of the lower ends of the outer skin material nozzles 47. However, the present invention is not limited thereto, and the lower end positions of the pipe members 41A and 41B are smaller than the outer skin materials. The lower end position of the mouth 47 may be located below. By adopting such an arrangement, when the suction is performed, the rod-shaped dough 19 in the region close to the solid objects A and B can be reduced toward the space 5A, 5B side by 201021713, and the surrounding inner packaging material 5 can be adhered to the solid matter. The effect of A and B is improved. In the example described here, the pistons 78A and 78B are formed in a hollow shape and suck air from the front end (lower end), but the passages of the pistons 78 A and 78B and the introduction guide 37 (the through hole 39A, the pipe member 41A, and the through hole 39B) A space for air suction is provided between the pipe members 41B), and air may be sucked from the lower ends of the pistons 78A and 78B. In detail, the aforementioned rod-shaped dough 19 is continuously discharged. The bottom of the rod-shaped surface group 19 is supported by the conveying device 25 which is raised from below, and then the conveying device 25 is lowered at substantially the same speed as the discharge speed of the rod-shaped dough 19 to be discharged. Further, the wrap-cutting device 21 cuts the rod-shaped dough 19 in a state where it is lowered from the raised position at a speed slightly faster than the discharge speed of the rod-shaped dough 19. Therefore, the rod-shaped dough 19 is sandwiched between the lower surface of the coating and cutting device 21 and the upper surface of the conveying device 25, and cut into the coated food 23. At this time, the solid matter a and the solid matter B in the coated food 23 are separated from each other by the inner package 5 being pushed between the solid a and the solid B. The present applicant has found that the means for suppressing the separation of the solid matter A and the solid matter B in the coated food 23 is the discharge port 45 A of the inner bag 45 and the discharge port 4 7 A of the outer mouth 47. Form an oblong or elliptical shape. Here, the step of covering and cutting the rod-shaped dough 19 by the six shielding members 21A provided in the coating and cutting device 21 will be described. The opening H of the regular polygon (positive hexagonal shape) surrounded by the six occluding bodies 21A is gradually reduced. Further, the rod-shaped dough 19' which is discharged from the outer skin material nozzle 47 (the overlapping nozzle 13) is discharged in a shape having an oval shape in a horizontal cross section, and flows down in the opening Η. First, the rod-shaped dough 19 is received from the long axis DL side of the oblong shape of the rod-shaped dough 19 from the side of the solid material A and the solid material B in the rod-shaped dough 19-17-201021713. Extrusion (see Figure 9 (la)). Then, the diameter of the opening 缩小 is reduced. At this time, the outer skin material 9 and the inner wrapping material 5 flow in the center direction along the long axis DL as a result of the pressing action from the shielding body 21Α. Further, since the short-axis DS side of the long circular shape of the rod-shaped dough 19 does not contact the shielding body 21, the outer skin material 9 and the inner packaging material 5 also flow outward along the short axis DS. Further, as the inner packaging material 5 flows in the center direction, the solid matter Α and the solid matter 暂时 are temporarily moved toward the center side and are close to each other. Then, the diameter of the opening 进一步 is further reduced, and the short axis DS side of the rod-shaped dough 19 is also pressed by the shielding body 21 ( (see Fig. 9 (lb)). The rod-shaped dough 19' is pressed substantially equally by the six shielding members 21A. Then, the opening Η is closed, and the rod-shaped dough 19 is covered and cut into the coated food 23 (see Fig. 9 (1 c)). At this time, the outer skin material 9 and the inner packaging material 5 are caused to flow toward the center by the narrowing of the opening diameter of the opening Η. Further, the inner wrapping material 5 also flows downward toward the lower side of the shielding body 21''. Therefore, the aforementioned inner packaging material 5 enters between the solid matter Α and the solid ’, and the solid matter A and the solid matter B are separated. However, in the coated food product 23, the interval between the solid objects A and B and the solid objects A and B disposed inside the rod-shaped dough 19 do not significantly change (refer to Figs. 7 and 9). (la) ~(1 <〇图). In addition, in the two-group solid material described in Patent Document 1, since the rod-shaped dough is superimposed in the vertical direction in an adhesive state, the interval between the solid objects may not be constant at the time of press molding in the next step. The problem. However, according to the first embodiment of the present invention, in the first embodiment of the present invention, the solid objects a and b can be manufactured by supplying the two solid materials A and B to the rod-shaped dough 19 in a state of being separated in the horizontal direction. The interval is stable to coat the food 23. The above is a description of the coating and cutting device 1 according to the first embodiment of the present invention, but various modifications can be made within the scope of the patent application. For example, use Figure 9(2a) (2b) (2c) for illustration. In the present example, the rod-shaped dough 91 which is discharged from the outer skin material nozzle 47 is discharged in a φ shape having a circular cross section, and the two solid materials are supplied to the inside of the rod-shaped dough group 91 in a separated state. The rod-shaped dough 91 is covered and cut by the six shielding members 21A provided in the covering and cutting device to produce a coated food 93 in which two solid materials are separated from each other in the horizontal direction. In the above, the food material constituting the rod-shaped doughs 19 and 91 is a two-layer structure composed of the inner packaging material 5 and the outer skin material 9. However, as long as a plurality of solid materials can be contained, it can be a single layer or A stick-shaped dough composed of three or more layers of food materials. Φ In addition, in the above description, the solid matter A and the solid matter B are respectively described in a solid form, but for example, a plurality of solid materials composed of a variety of gamut beans may be grouped in a receiving hole 65, A plurality of solid matter groups are accommodated in a plurality of locations in the coated food product 23. Also in this case, a plurality of solid matter groups are disposed in the horizontal direction inside the coated food product 23. In addition, the attraction by the suction device can be effectively performed. Further, the solid matter (solid group) supplied to the rod-shaped doughs 19, 91 at one time is not limited to two, and for example, three may be used. In this case, as shown in Fig. 8(b), the shape of the discharge port 45J of the inner package 45 and the discharge port 47J of the outer cover 47 -19 to 201021713 are substantially triangular (the angle of the equilateral triangle) The shape is deformed in an arc shape) and the directions are the same. Further, the three pipe members 41A, 41B, and 41C are disposed inside the discharge port 45J at the same distance from the center of the discharge port 45 J and along the direction from the center to the respective corner portions (with the aforementioned triangle) The directions of the respective corners are synonymous. Here, the 'direction is regarded as the direction of the long axis DL' is configured. In the discharge port 47J, for example, when the openings J formed by the three shielding members 21 B are aligned in the direction shown in Fig. 8(b), the entire circumference of the rod-shaped dough is not in the initial stage of the coating cutting step. It will be uniformly squeezed to move the solid object toward the center side. Then, the inner packaging material pressed by the shielding body 21B can be moved toward the outer peripheral side of the coated food in the direction of the short axis DS, and can be coated in such a manner that the solid matter is not offset at the outer periphery of the coated food. Cut off. The short axis DS is arranged in a direction in which the angle formed by the three long axes DL are equally divided. Further, the same applies to the case of manufacturing a coated food containing four solid materials. Next, a coating and cutting device 1 according to a second embodiment of the present invention will be described with reference to Figs. 10 to 14 . The constituent elements that exhibit the same functions as those of the first embodiment are denoted by the same reference numerals, and the description thereof will not be repeated. In the rotary disk 64 of the solid-state supply device 57 of the second embodiment, 15 receiving holes 92 are provided at equal intervals on the circumference Pi. The receiving hole 92 has a shape in which a plurality of identical circular holes (the first receiving hole 92A and the second receiving hole 92B) are partially overlapped in a plan view, that is, a shape of a so-called 8-shaped outer shape (referred to herein as a partial portion). Stacked circles). Further, the center of the first receiving hole 92 A and the second receiving hole 92B is disposed at an equal distance from the center of the rotary disk 64. Further, the opening 63 B of the tray 63 is formed in a shape corresponding to the above-described receiving hole 92. Further, between the opening 63B of the tray 63 and the seat plate 59B, a shutter 87 that reciprocates in the horizontal direction is disposed. When the rotating disk 64 rotates, the shielding plate 87 is located below the opening 63 B to stop the solid material A and the solid material B from falling. When the rotating disk 64 stops at a predetermined position, the shielding plate 87 is an inward packaging material hopper. 7 or the outer skin material hopper 11 side (the upper side of Fig. 10, the right side of Fig. 12) is horizontally moved. Further, the solid material A and the solid material B are accommodated in the first receiving hole 92A and the second receiving hole 92B, respectively, and the rotating φ disk 64 is intermittently oriented in one direction at a time of 24 degrees (the inverse of FIG. 10) Rotate in the hour hand direction to intermittently supply the solid matter A and the solid matter B into the stacking nozzle 13 at the same time. An introduction guide 94 is provided inside the inner cylinder 35 of the stacking nozzle 13. The introduction guide 94 has a flange member 95. The protruding portion 95D formed on the lower surface of the flange portion 95C of the flange member 95 is fitted into the concave slit 35B of the inner cylinder 35, thereby being positioned such that the through hole 97 and the aforementioned stop are stopped The receiving holes 92 of the rotary disk 64 are formed concentrically. © The pipe member 96 is fitted to the flange member 95. The pipe member 96 is formed with a through hole 97 (passage) having a figure 8 shape (partially overlapping circle) similar to the receiving hole 92 as viewed from above. The through hole 97 is composed of the first through hole 97A and the second through hole 97B, and is formed symmetrically with respect to the center line of the flange member 95. The width of the through hole 97, that is, the length in the longitudinal direction DL direction in plan view is longer than the diameter of the circle forming the respective through holes 97A and 97B, and is shorter than twice the diameter of the circle; in this example, the diameter of the circle丨.9 times. Further, the through hole 97' is formed with a facing inner protruding portion 97c (a portion where the circular arc of the first through hole 97A and the second through hole 97B intersect). Since the interval of the inner protruding portion 97C with respect to the -21 to 21,217,213 is shorter than the diameter of the circle forming the respective through holes 97A and 97B, the solid objects A and B supplied from the rotary disk 64 do not intrude into the opposite through hole 97A, 97B, and falls in the through hole at a position close to each other. The outer shape of the pipe member 96 is such that a forward (similar) through hole 97 is formed, and a concave portion 97D is formed on the short diameter DS as viewed from the top (see Fig. 14). Further, at the lower end portion of the pipe member 96, an inclined portion 97TA and an inclined portion 97TB are formed symmetrically at both ends of the long diameter DL of the through hole 97 (refer to Fig. 11). Further, the upper ends of the inclined portions 97TA and the inclined portions 97TB are located above the discharge port 45C of the inner package nozzle 45, and the lower end (that is, the lower end of the pipe member 96) is located below the discharge port 45C ( Refer to Figure 11). Further, the discharge port 45C of the inner package material nozzle 45 and the discharge port 47C of the outer material material nozzle 47 are formed in a circular shape. Two rods 77A, 77B are provided in the pushing device 71 of the solid material supply device 57. At the lower end portions of the rod 77A and the rod 77B, a piston member 98 for connecting them or the like is screwed. Pistons 98A, 98B which are concentric with the rods 77A, 77B, respectively, are disposed at the lower portion of the piston member 98. Further, on the lower surface of the piston 98 A and the piston 98B, inclined surfaces 98TA and inclined surfaces 98TB which are opposed to each other and which are enlarged downward are formed. The piston member 98 is provided to be inserted into a receiving hole 92 of the rotating disk 64 after the rotation is stopped, and a through hole 97 provided in the lead guide 94 of the stacking nozzle 13. Further, the rods 77A and 77B and the pistons 98A and 98B are formed in a hollow shape, and the upper ends of the rods 77A and 77B are connected to a suction device (not shown). Here, the step of coating and cutting the second embodiment of the present invention will be described. -22- 201021713 A stick-shaped dough 19 is discharged from the lower side of the stacking nozzle 13. The rod-shaped dough 19 is formed by coating the inner wrapping material 5 with the outer skin material 9 to form a two-layer structure. The inner packaging material 5 is discharged from the discharge port 45C of the inner packaging material nozzle 45 through the inner circumferential surface of the inner packaging material nozzle 45 and the outer circumferential surface of the pipe member 96 into which the guide 94 is introduced. At this time, since the inner wrapper 5 flows down along the outer shape of the pipe member 96, the space 6A and the space 6B are integrated to form the bag-shaped space 6 inside the inner wrapper 5. The bag-shaped space 6 is formed in the shape of a partial overlapping circle having a horizontal cross section and a figure of eight. In addition, the inner packaging material 5 which flows downward from the lower end of the pipe member 96 flows downward in the center direction as the outer diameter of the outer skin material nozzle 47 becomes smaller, and the inner bag is formed in the shape of the bag. Space 6 becomes smaller. Further, since the inclined portions 97TA and 97TB are provided at the lower end of the pipe member 96, the inner packaging material 5 first flows from the long diameter DL side of the pipe member 96 toward the pocket-shaped space 6 side compared with the other lower end portions, so that the aforementioned The pocket space 6 is reduced. The rotary disk 64 of the solid material supply device 57 is rotated by 24 degrees in the direction of the arrow T and then stopped again. Then, when the shielding plate 87 moves from the lower side of the rotary disk 64 to the outer side, the solid objects A and B are simultaneously dropped from the first receiving hole 92A and the second receiving hole 92B of the rotating disk 64, and are individually supplied to the inner packaging material. 5 spaces 6A, 6B. Further, while the rotating disk 64 stops rotating, the rodless cylinder of the push-in device 71 is driven, and the first piston 98A and the second piston 98B of the piston member 98 stopped at the rising position are respectively along the receiving hole 92A. 92B. The inside of the first through hole 97A and the second through hole 978 of the pipe member 96 of the introduction guide 94 are lowered. Further, the inclined surface 98 of the piston 98 and the inclined surface 98TB of the piston 98B press the solid A and the solid B toward the center obliquely downward, and the solid A and the solid B move to approach each other and form. -23- 201021713 The inner packaging material 5 at the bottom of the bag-like space is in close contact with each other, and the inner packaging material 5 is interposed between the solid matter A and the solid material B, and is disposed in a horizontal direction so as not to be in close contact with each other. The inclined surface 98TA of the piston 98A and the inclined surface 98TB of the piston 98B are pressing surfaces for pressing the solid material A and the solid material B toward the center, and the shape is not limited to a plane, and may be a curved surface, a curved surface, or the like, as long as It is a structure that can squeeze a solid object to a desired position. The piston member 98 that has been lowered to the lowering stop position is again raised. The suction device is operated to suck the air in the bag-shaped space 6 of the inner package 5 from the front ends of the hollow first piston 98 A and the second piston 98B before and after the rise or rise of the piston member 98. The coating cutting operation 21 is operated to produce the coated food 23 in which the solid objects A and B are wrapped in the horizontal direction from the rod-shaped dough 10. In the same manner as the coating and cutting step of the first embodiment, between the lower surface of the coating and cutting device 21 and the upper surface of the conveying device 25, the rod-shaped dough 19 containing the solid material A and the solid material B is sandwiched. And cut into coated food 23 . More specifically, the stick-shaped dough 19 discharged from the outer skin material nozzle 47 flows downward along the opening ,, and is shrunk as the opening Η is positioned above the solid material 固态 and the solid material B in the rod-shaped dough 19. The diameter is subjected to equal pressing from the six shields 21A. At this time, the outer skin material 9 and the inner packaging material 5 flow in the center direction and the upper and lower directions of the shielding body 21A (the vertical direction of the paper surface in Fig. 13) by the pressing action of the shielding body 21 A. Therefore, the inner wrapping material 5 shrinks the pocket-shaped space 6 and enters between the close solid matter a and the solid material B, and gradually separates the solid matter A and the solid matter B. Then, the opening η - 24 - 201021713 is further reduced in diameter, and is cut from the rod-shaped dough 19 into the coated food 23 . During this period, the aforementioned inner packaging material 5 continues to enter between the solid material A and the solid material B, and the solid material A and the solid material B are further separated. Then, by solid-forming the coated food 23, the solid A and the solid B in the final product are arranged in the horizontal direction at appropriate intervals. Further, in conjunction with the cutting operation of the coating and cutting device 21, the suction device φ is operated to move from the hollow first piston 98A and the second piston 98B before and after the piston member 98 is raised or raised. The tip end of the bag attracts the air in the bag-shaped space 6 of the inner bag member 5, thereby reducing the pressure in the bag-shaped space 6 in which the solid objects A and B are accommodated. Therefore, the inner covering material 5 around the solid objects A and B moves and adheres to the solid materials A and B, and the gap formed between the solid materials A and B and the inner wrapping material 5 can be suppressed. In the coating and cutting device 1 according to the second embodiment of the present invention, the shape of the discharge port 45C of the inner packaging material nozzle 45 and the discharge port 47C of the outer material material nozzle 47 is a circular shape. The oblong shape or the elliptical shape may be formed in the same manner as the first embodiment of the first embodiment of the present invention, and the shielding body 21A may be disposed corresponding to the shape thereof. As can be understood from the above description, a plurality of solid objects can be individually dropped in the individual passages (the tube members 41A and 41B, the first through holes 97A and the second through holes 97B), and can be made in the rod-shaped dough. A plurality of solid objects are arranged in the horizontal direction and are supplied in a manner that is not in close contact with each other. Densely packed the bow material, the food is allowed to pass through the food, and the vacant bow of the living air is loaded with the air supply. The object is made up of the bag. 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 Fig. 2 is a side view showing a main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention, and a part thereof is shown in cross section. Fig. 3 is a plan view showing a main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention. Fig. 4 is a cross-sectional view taken along the line X-X of Fig. 3, showing a main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention. Fig. 5 is a cross-sectional view taken along line Y-Y of Fig. 3, showing a main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention. Fig. 6 is a cross-sectional view showing the main assembly of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention, and is a cross-sectional view for explaining the assembly procedure of the respective portions of Fig. 5. Fig. 7 is a front elevational view showing the main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention, and a part thereof is shown in cross section. Fig. 8(a) and Fig. 8(b) are diagrams showing the main part of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention. In the drawings, the main parts of the coated food product manufacturing apparatus 1 according to the first embodiment of the present invention are schematically shown. Fig. 1 is a plan view showing a main part of a coated food product manufacturing apparatus 1 according to a second embodiment of the present invention. Fig. 11 is a cross-sectional view showing the wrapped food of the second embodiment of the present invention. -26- 201021713 The main portion of the manufacturing apparatus 1 is a w-w line of the first drawing. Fig. 12 is a cross-sectional view taken along line V-V of Fig. 10, showing a main part of the coated food product manufacturing apparatus 1 according to the second embodiment of the present invention. Fig. 13 is a front elevational view showing the main part of the coated food product manufacturing apparatus 1 according to the second embodiment of the present invention, and a part thereof is shown in cross section. In the first embodiment, the main part of the coated food product manufacturing apparatus 1 according to the second embodiment of the present invention is a cross-sectional view taken along line z-z of Fig. 10 . ❹ [Description of main component symbols] 1 : Coated food manufacturing device 2: Stuffing machine 3: Rack 5: Inner wrap 5A' 5B, 6: Pocket space 6A, 6B: Space φ 7: hopper 8 for inner packaging material 12: screw 9: outer skin material 10, 14: impeller pump 1 1 : outer skin material hopper 13 : superimposed nozzle 15 : inner packaging material supply device 17 : outer skin material supply device 19 , 91 : rod-shaped dough -27 - 201021713 2 1 : Covering and cutting device 21A, 21B: shielding body 23, 93: coated food 25: conveying device 25A: conveying belt 25B: driving pulley 26: upper and lower moving plate 27: stirring rotating member 27A: stirring member 3 1 : Upper housing 32: outer cylinder 32A, 32B: connection port 32C: cylinder portion 3 3 : lower housing 3 5 : inner cylinder 35A, 35B: concave slit 3 7 : introduction guide 39, 79, 95: flange member
39A、39B、97:貫通孑L 39C、95C:凸緣部 39D、95D:突條部 41A ' 41B ' 41C、96:管構件 43 :銷構件 45 :內包材用嘴 -28- 20102171339A, 39B, 97: through 孑L 39C, 95C: flange portion 39D, 95D: rib portion 41A ' 41B ' 41C, 96: pipe member 43 : pin member 45 : mouth for inner packaging material -28- 201021713
45A、45C 4 7 :外皮材 47A、47C、 47B ' 49B : 49 :外殼 51 、 83 :螺 5 3 :定位銷 55 :銷 5 7 :固態物 5 9 :座部 59A :基端i 59B :座板 61 、 67 :緊 63 :托盤 63A、63B : 64 :旋轉盤 65 :旋轉盤 65A、65B : 69 :旋轉軸 71 :推入裝 73 :支架 75 :無桿式 7 5 A :滑動4 75B :保持j 45J:內包材用嘴的吐出口 用嘴 47J :外皮材用嘴的吐出口 嵌合溝槽 帽構件 供應裝置 固螺釘 托盤的開口 收容孔 置 氣缸 -29 - 201021713 7 7 A、7 7 B :桿件 78A ' 78B :活塞 79A、79B :貫通孔 79C :嵌合凹部 7 9 Η :嵌合孔 8 1 :防振板 8 1 A :插通孔 87 :遮擋板45A, 45C 4 7 : outer skin material 47A, 47C, 47B ' 49B : 49 : outer casing 51 , 83 : screw 5 3 : positioning pin 55 : pin 5 7 : solid matter 5 9 : seat portion 59A : base end i 59B : seat Plates 61, 67: Tight 63: Pallets 63A, 63B: 64: Rotating disc 65: Rotating discs 65A, 65B: 69: Rotary shaft 71: Push-in 73: Bracket 75: Rodless 7 5 A: Sliding 4 75B: J 45J: Exhaust port nozzle 47J for the inner packaging material nozzle: Discharge port fitting for the outer material material nozzle Groove cap member supply device Open screw tray opening receiving hole for the cylinder -29 - 201021713 7 7 A, 7 7 B: Rod 78A '78B: Pistons 79A, 79B: Through hole 79C: fitting recess 7 9 Η : fitting hole 8 1 : anti-vibration plate 8 1 A : insertion hole 87 : shielding plate
9 2 :收容孔 92A :第1收容孔 92B:第2收容孔 94 :導入導件 97A :第1貫通孔 97B:第2貫通孔 97C :突出部 97D :凹部9 2 : receiving hole 92A : first receiving hole 92B : second receiving hole 94 : introduction guide 97A : first through hole 97B : second through hole 97C : protruding portion 97D : concave portion
97TA > 97TB、98TA、98TB :傾斜部 9 8 :活塞構件 98A ' 98B:活塞 A、B :固態物 DL :棒狀麵團的長軸 DS:棒狀麵團的短軸 Η、J :開口 Ρ、Q :旋轉盤的圓周 R、Rl、R2 :環狀空間 -30-97TA > 97TB, 98TA, 98TB: inclined portion 9 8 : piston member 98A ' 98B: piston A, B : solid matter DL : long axis of the stick dough DS: short axis of the stick dough, J: opening Ρ, Q: The circumference of the rotating disk R, Rl, R2: annular space -30-