201011138 六、發明說明: 【發明所屬之技術嘴域】 技術領域 機 。本發明係《於-種搭载Μ筒式洗衣 器,調節循環空氣之空調單元。 ,、衣機# C先前技】 背景技術 習知之空調單元係在滾筒式洗衣烘衣機 背部之死空間而内設,連接於 用其水槽 徑之途中。藉此,《送風路徑:::=環送風路 仃洗滌步驟或洗刷步驟後之乾燥步驟,作以執 扇之驅動,將水槽内之空氣吸引排出,:空調:?:風風 引導入口導人,供蒸發器之除濕、冷凝器之加Ρ從其吸 燥之空氣後,從吸引排出口排出,送她而形成乾 槽内,而钱轉賴内之絲物鶴。切侧,返回水 因此,在具有空氣之吸引導人口及 殼軍内’於空調殼罩之前後相對壁間形成從別 吸弓丨排出Π之通風純。將在此通風路 、 加熱之蒸發器及冷凝器分隔配置於面 空氣除:最 J之吸引導入側及面向前部壁之吸引排出側:= 罩之頂壁之後部壁側,設置成朝 =述吸引導人側,吸引排出口設置於空顿罩之端部壁 之下部,從側邊通往前逑吸引排出側。 另一方面,在熱交換區域,設置貯存因蒸發器之除濕 3 201011138 功能產生之凝結水或因某些理由進入之水等之貯存部。貯 存於貯存部之水以排水泵排出。在此,由於伴隨循環空氣 而來之線渣等異物流入時,成為排水泵之堵塞或動作不声 之原因’故習知於貯存部之開口設有過濾器。此外 上迷 技術内容揭示於日本專利公開公報2008-79861號。 則堆積 ’而使201011138 VI. Description of the invention: [Technical field of invention] Technical field Machine. The present invention is an air conditioning unit that regulates circulating air in a type of cartridge-type laundry machine. BACKGROUND OF THE INVENTION The conventional air conditioning unit is built in the dead space on the back of the drum type washing and drying machine, and is connected to the path of the water tank. Thereby, the air supply path:::=the air supply path, the washing step after the washing step or the washing step, the driving of the fan, the air in the water tank is sucked and discharged, the air conditioner:?: the wind guides the entrance guide For the dehumidification of the evaporator and the condensation of the condenser, the air is sucked from the suction outlet, and is sent out to form a dry trough, and the money is transferred to the silk crane. Cut the side and return the water. Therefore, in the air-suction-guided population and the shell army, the ventilation of the sputum is removed from the opposite wall after the air-conditioning casing. The air passage, the heated evaporator and the condenser are arranged in the surface air except for: the suction side of the most J and the suction side facing the front wall: = the wall side of the top wall of the cover, set to = The suction guide side is provided, and the suction discharge port is disposed at a lower portion of the end wall of the hollow cover, and leads to the front side suction suction side from the side. On the other hand, in the heat exchange area, a storage portion for storing condensed water due to the function of dehumidification of the evaporator 3 201011138 or water entering for some reason is provided. The water stored in the storage portion is discharged by a drain pump. Here, when the slag or the like is caused to flow in accordance with the circulating air, the drain pump is blocked or the operation is not sounded. Therefore, it is known that a filter is provided in the opening of the storage portion. Further, the technical content is disclosed in Japanese Patent Laid-Open Publication No. 2008-79861. Then pile up
然而,習知之空調單元以過濾器阻止線渣時, 於過濾器,而阻礙排水性能,故必須定期卸除清掃 洗衣烘衣機使用上繁雜。 C 明内】 發明揭示 以致 過濾 本發明係提供將在熱交換區域產生或聚集之水類 力於線渣等異物不往前流動之排水路徑排出,而不需 器及其保養之空調單元。However, the conventional air conditioning unit uses a filter to block the wire slag when it is in the filter, which hinders the drainage performance, so it is necessary to periodically remove the cleaning. The washing and drying machine is complicated to use. In the present invention, the present invention provides an air conditioning unit which discharges a water path generated or accumulated in a heat exchange area to a drainage path in which a foreign matter such as a slag does not flow forward without requiring a device and maintenance thereof.
本發明之空調單元係在具有空氣之吸引導入口 排出口之單元殼罩内,於吸引導入口至吸引排出口 路徑之熱交換區域,將空氣除濕加熱之除濕用熱交換^ 加熱用熱交換器分隔配置於吸引導入侧熱交換區域與= 排出側熱交換區域者,將在熱交換區域產生之水_趣% 前述熱交換區域之底部設有作為阻止異物不往前流^_ 檔部之突起或及收縮部的排水路徑排出。 藉此種結構,可以配置在形成於單元殼罩之吸 導入〇及吸引排出口間之熱交換區域之除濕用熱 加熱用熱交換器,將吸引空氣作為經除濕及加熱、 高溫空氣而連續送出。特別是在通風路徑之熱交換^ 4 201011138 反覆進行以下動作,即’將與除濕用熱交換器熱交換之空 氣中之水分分離作為凝結水等之水類經由排水路徑,排出 至外部。以作為阻擂部而設置於此排水路徑之突起或及收 縮部阻止捕捉線渣等異物而不致往前流動,故即使無過濾 器,亦可防止異物進入排水泵。 又’本發明之空調单元係在具有空氣之吸引導入口及 吸引排出口之單元殼罩體内,於吸引導入口至吸引排出口 % 之通風路徑之熱交換區域,將空氣除濕加熱之除漁用熱交 換器及加熱用熱交換器分隔配置於吸引導入側熱交換區域 與吸引排出側熱交換區域者,於熱交換區域之底部設有設 . 置成承接從除濕用熱交換器流下之凝結水,並將之排出的 凝結水排水盤、積聚滴下或流動落下至除濕用熱交換器之 及引導入側熱交換區域之側的水等的集水部、及將從該集 水部之一部份環繞凝結水排水盤之外圍,並通往凝結水排 水盤而將於集水部聚集之水引導排出至凝結水承接盤的輔 # 助排水盤。並且,於該輔助排水盤及凝結水排水盤中,至 少於輔助排水盤之排水路徑設置作為阻止異物不往前流動 之阻擒部的突起或收縮部。 藉此種結構,以在空調殼罩之吸引空氣導入口與吸引 排出口間’形成在空氣殼罩之相對側壁間之通風路徑的熱 交換區域’分隔配置於吸引導入側熱交換區域及吸引排出 側熱交換區域之除濕用熱交換器與加熱用熱交換器將吸引 二氧作為經除濕及加熱而乾燥之高溢空氣而連續送出。特 别是可將與除濕用熱交換器熱交換之空氣中之水分分離作 5 201011138 為凝結水之水承接至凝結水排水盤,經由排水路徑,排出 至外部。又,滴下或流動落下至除濕用熱交換器之吸引導 入側熱交換區域側之水類一面積聚於集水部,一面從此集 水部之一部份經由環繞前述凝結水排水盤外圍之輔助排水 盤,引導至凝結水排水盤,而可在無專用排水系統下排水。 再者,因應在吸引導入側熱交換區域側附著於除濕用熱交 換器之吸氣面側,易與凝結水一同流動落下,而以設置於 輔助排水盤及凝結水排水盤中之至少輔助排水盤之排水路 徑之作為阻擋部的突起或收縮部阻止捕捉線渣等異物而不 致往前流動。是故,即使無過濾器,亦可防止異物進入排 水泵。且可不致於如過濾器之網眼般產生堵塞,而可免於保 養。 在上述中,輔助排水盤以收縮部通往凝結水排水盤。 藉此種結構,輔助排水盤亦可以通往凝結水排水盤之 收縮部作為阻擋部,阻止線渣等異物,而可防止進入至連 接於排水系統之凝結水排水盤側。 在上述中,前述除濕用熱交換器及前述加熱用熱交換 器形成相互之散熱片排列成並排之熱交換部,前述除濕用 熱交換器直立設置於前述凝結水排水盤上,前述加熱用熱 交換器直立設置於前述輔助排水盤上。 藉此種結構,除濕用熱交換器及加熱用熱交換器相互 之散熱片排列成並排,在該等之間可避免因空間上浪費, 而形成成為循環空氣之流動旁路至吸引排出口側之原因的 隔離空間。將除濕用熱交換器直立設置於凝結水排水盤上 201011138 來覆蓋,而可將凝結水在無線渣等之伴隨或從周圍進入下 承接而排出。此外,輔助排水盤利用直立設置於其上之加 熱用熱交換器之下部空間而發揮作用。 在上述中,前述輔助排水盤通往前述熱交換區域之前 述吸引排出側熱交換區域之底部。藉前述輔助排水盤通往 前述熱交換區域之前述吸引排出側熱交換區域之底部,即 使在吸引排出侧熱交換區域側因某些理由有水進入,亦可 經由輔助排水盤、凝結水排水盤排水。 圖式簡單說明 第1圖係本發明實施形態之空調單元裝設於滾筒式洗 衣烘衣機之側面圖。 第2圖係本發明實施形態之空調單元裝設於滾筒式洗 衣烘衣機之背面圖。 第3圖係顯示於本發明實施形態之空調單元連接送風 風扇之空調風扇單元之截面圖。 第4圖係本發明實施形態之空調單元之壓縮機之收容 區域及與其分隔,作為送風通路一部份之一端側後部區域 的橫截面圖。 第5圖係本發明實施形態空調單元之熱交換區域之橫 截面圖。 第6圖係卸除單元殼罩之上分割構件而觀看本發明實 施形態之空調單元之平面圖。 第7圖係在第6圖之狀態下從斜方觀看本發明實施形態 之空調單元之立體圖。 7 201011138 第8圖係從前部側觀看本發明實施形態之空調單 外觀立體圖。 第9圖係從上部觀看本發明實施形態之空調單元 觀平面圖。 ^ 第10圖係切明實卿態空鮮元之單元殼罩 割構件之平面圖。 n 第11圖係第10圖之下分割構件之立體圖。 第I2圖係本發明實施形態空調單元之單元般罩之上分 割構件之下面¢1。 73 / 參 第13圖係_示内設於本發明實施形態空調單元之壓縮 機與彈性座體<組合狀態之立體圖。 第14圖係在第6圖之狀態下從吸引排出側斜上觀看本 發明實施形態、單元之部份立體圖。 第15圖係從收容區域側觀看本發明實施形態之空調單 ' 元之側面圖。 【贺"方包】 用以實施發明之最佳形態 響 就本發明實施形態之空調風扇單元,參照第1圖〜第15 圖,說明以下,以供理解本發明。以下之說明為本發明之 具體例,非限定申請專利範圍之内容者。 第1圖、第2圖係本發明實施形態空調單元裝設於滾筒 式洗衣烘衣機者。在第1圖、第2圖中,滚筒式洗衣烘衣機j 係在洗衣烘衣機本體44内,水槽3以圖中未示之懸吊構造配 設成浮動狀態,在水槽3内,形成有底圓筒形之旋轉滾筒2 8 201011138 使其軸心方向從正面側朝向背面側向下傾斜配設。於水槽3 ' 之正面侧形成通往旋轉滾筒2之開口端之衣類出人叫,藉 • 肖啟將設置於形成在洗储衣機本體44正面侧之朝上傾斜 面之開口部可開關地關閉之門9,經由前述衣類出入口u, 對旋轉;袞筒2内取出放入洗務物。由於門9設置於朝上傾斜 面,故可在不彎腰下執行取出放入洗滌物之作業。 於旋轉滾筒2之周面形成通往水槽3内之複數個透孔 φ 8 ’於内周面之圓周方向複數位置設有授拌突起(圖中未 ^)。此旋轉滾筒2以安裝於水槽3背面側之馬達7於正轉及 方向旋轉驅動。又’於水槽3配管連接注水管路12及排 '^路13以®巾未不之注水閥及排水閥之控制進行對水 槽3内之注水及排水。 .· 開啟H9 ’將洗騎及洗潔騎人至旋轉滾筒2内,以 設置於滾筒式洗衣烘衣機!之前面上部之操作面板的之操 作’經由亦設於其内側等之控制基板67之控制,開始運轉 • 時’在水槽3内,從注水管路12進行預定量之注水,以馬達 旋轉驅動方疋轉滚筒2,開始洗務步驟。以旋轉滾筒2之旋 2 ’反覆進行收容於旋轉滾筒2内之洗務物以設置於旋轉滾 内周壁之獅突起被舉起至旋轉方向,從被舉起之適當 而-置落下之攪拌動作,故拍洗之作用對洗滌物發揮, =進行洗蘇。於所需之歸時間後,⑽之洗祕從排水 路13排出’以使旋轉滚筒2高速旋轉之動作,將洗滌物所 含之洗條液脫水’之後,從注水管路12注水至水槽3内,執 行洗刷步驟。在此洗刷步驟,收容於旋轉滾筒2内之洗務物 201011138 乂疑轉滚筒2之;$疋轉,反覆執行藉授拌突起被舉起而落下之 攪拌動作’而執行洗刷。 於此滾筒式洗衣烘衣機1設置使收容在旋轉滾筒2内之 洗務物乾社魏。因此,料式洗衣烘衣機丨如前述,内 =空調風扇單元39、將水槽3内之空氣吸引排氣,將導入至 工調風扇單S39,供除濕、加熱而乾燥之高溫空氣再送至 水槽3内之循環送風路徑5,在循環送風路徑5之比空調風扇 單元39還下游處設有送風風扇15。 , S旋轉驅動此送風風扇15時,於循環送風路徑5產生空 軋之流動,收容有洗祕之旋轉滾筒2内之舰空氣經由透 孔8 ’以水槽3至送風風扇15側之循環空氣導人管路⑽引 排氣。此排氣之潮濕空氣從吸引導人口 391導人至直接連結 於送風風扇15之上游侧之空賴扇單元%的通風路徑内, 於位在其途中之蒸發||31使空氣中之水分凝結而除濕並 且以與冷凝H32之熱交換加熱,而作為平常乾燥之高溫空 氣此乾燥之兩溫空氣經由吸引排出口392,吸引至送風風 扇b後’送出至水槽3之送風管路33,送風至水槽3内。送 風至水槽3内之高溫乾燥空氣經由透孔8,進入旋轉滾筒2 内,一面接觸衣類等洗滌物,一面通往水槽3,再度導入至 循環空氣導人管路16,以以上在循環送風路徑5之空氣之反 覆循環,執行乾燥步驟。 此外,在利用此循環送風路徑5之乾燥步驟甲,在循環 送風路控5循環之空氣中,主要從衣類等洗滌物產生之線法 等異物混入而循環,蒸發器31或冷凝器32之堵塞、咬入至 201011138 送風風扇15旋轉部、在送風風扇15内面之堆積易對執行乾 燥步驟造成障礙,而需頻繁地進行繁複之保養,故一般在 循環送風路徑5之途中,具體為蒸發器31、冷凝器32、送風 風扇15之上游側,因而,於前述循環空氣導入管路16之途 中設置收容有用以去除循環空氣中之異物之過濾器35。藉 此,即使異物混入至使洗梅物乾燥後之空氣,導入至蒸發 器31侧之循環空氣導入管路16側,在通過過濾室允時,以 過濾、器35捕冑,而;f致混入至下游側之循環空氣。因而, 可長期保持蒸發器31、冷凝器32、送風風扇15之功能。然 而,另一方面,所捕集之異物堆積於過濾室36之過濾器35, 循環空氣之通過阻力逐漸增加,使乾燥功能降低,故過滤 器35與一般同樣地設置成可拆卸。又,空調風扇單元刊以 與送風風扇15之直接連結,構成以單體處理該等之空調風 扇單元81,但不限於此。 在此,產生凝結水之蒸發器31與冷凝器32一同構成熱 父換部395,於空調殼罩38之對應於底部除濕區域之範圍設 置凝結水之貯存部63,連接具有排水泵64之排水管路幻, 以圖中未示之水位感測器之水位檢測之基準,進行適當之 排水。然而,但因某些排水異常’水位異常上升時,有所 貯存之凝結水到達循環送風路徑5之其他部份之可能性。因 此,熱交換部設置成位於循環送風路徑5之最低部位。 如以上,搭戴於各種機器而運作之空調風扇單元扣對 搭載之機器之大型化、製品價格、保養工夫、運轉費用造 成影響’故期望小型化、零件件數、組裝工數之刪減、^ 11 201011138 換零件之刪減。 *知於本發明實施形態之空調單元連接送風 風扇單元之截面圖。第4圖係本發明實施形態之 :邱二一壓縮機之收容區域及與其分隔,作為送風通路 开n™端側後部區域之橫截面圖。第5圖係本發明實施 =工調^之熱交換區域之橫截面圖。第6_卸除單元 >割構件而觀看本發明實施形態之空調單元之平The air conditioning unit according to the present invention is a heat exchanger for heat removal by dehumidification of the air in the heat exchange area between the suction introduction port and the suction discharge port in the unit casing having the air suction introduction port discharge port. The separator is disposed between the suction introduction side heat exchange area and the = discharge side heat exchange area, and the water generated in the heat exchange area is provided at the bottom of the heat exchange area as a protrusion for preventing foreign matter from flowing forward. Or drain the drainage path of the constriction. With this configuration, the heat exchanger for heat removal for dehumidification formed in the heat exchange region between the suction inlet and the suction discharge port of the unit casing can be disposed, and the suction air can be continuously sent out as dehumidified and heated, high-temperature air. . In particular, in the heat exchange of the ventilation path ^ 4 201011138, the water in the air exchanged with the heat exchanger for dehumidification is separated as water such as condensed water and discharged to the outside through the drainage path. The projections provided in the drainage path as the damming portion and the constricted portion prevent foreign matter such as wire slag from being caught, so that the foreign matter can be prevented from entering the drain pump even without the filter. Further, the air conditioning unit of the present invention is provided in a unit casing having an air suction introduction port and a suction discharge port, and dehumidifying and heating the air in a heat exchange region of the ventilation path from the suction introduction port to the suction port. The heat exchanger and the heat exchanger for heating are arranged to be disposed between the suction introduction side heat exchange area and the suction discharge side heat exchange area, and are disposed at the bottom of the heat exchange area to receive condensation from the dehumidification heat exchanger. a condensate drain pan for discharging water, and a water collecting portion that collects or drops or flows down to the heat exchanger for dehumidification and the water that is introduced into the side heat exchange region, and one of the water collecting portions from the water collecting portion Partially surrounding the periphery of the condensate drain pan, and leading to the condensate drain pan, the water collected in the catchment portion is guided to the auxiliary #助排水盘 of the condensate receiving pan. Further, in the auxiliary drain pan and the condensate drain pan, the drain path to the auxiliary drain pan is provided as a projection or a contraction portion for preventing the foreign matter from flowing forward. With this configuration, the heat exchange area of the ventilation path between the suction air introduction port and the suction discharge port of the air-conditioning case is formed in the heat exchange area of the suction side, and is sucked and discharged. The heat exchanger for dehumidification in the side heat exchange area and the heat exchanger for heating continuously suck the dioxane as high-spirit air which is dried by dehumidification and heating, and continuously sent out. In particular, the moisture in the air exchanged with the heat exchanger for dehumidification can be separated as 5 201011138 The water for the condensate is taken up to the condensate drain pan, and discharged to the outside via the drain path. Further, one area of the water that has been dropped or flowed down to the side of the heat exchange region on the side of the suction side of the heat exchanger for dehumidification is collected in the water collecting portion, and one part of the water collecting portion is surrounded by the periphery of the condensed water draining disk. The drain pan guides to the condensate drain pan and drains without a dedicated drainage system. In addition, it adheres to the side of the suction side of the heat exchanger for dehumidification on the side of the suction side of the suction side, and is easily flowed down together with the condensed water, and at least the auxiliary drainage provided in the auxiliary drain pan and the condensate drain pan The protrusion or the constricted portion of the drain path of the disk as a blocking portion prevents foreign matter such as wire residue from being caught without flowing forward. Therefore, even if there is no filter, foreign matter can be prevented from entering the drain pump. It can not be blocked as the mesh of the filter, and can be protected from maintenance. In the above, the auxiliary drain pan leads to the condensate drain pan at the constricted portion. With this configuration, the auxiliary drain pan can also be guided to the constricted portion of the condensate drain pan as a stopper to prevent foreign matter such as wire slag from being prevented from entering the condensate drain pan side connected to the drainage system. In the above, the heat exchanger for dehumidification and the heat exchanger for heating form a heat exchange unit in which the fins are arranged in parallel, and the heat exchanger for dehumidification is erected on the condensate drain pan, and the heat for heating is used. The exchanger is erected on the aforementioned auxiliary drain pan. With this configuration, the heat dissipating fins of the dehumidifying heat exchanger and the heating heat exchanger are arranged side by side, and between these, it is possible to avoid the waste of space, and the flow bypassing to the suction discharge port side is formed. The isolation space for the reason. The heat exchanger for dehumidification is placed upright on the condensate drain pan 201011138 to cover, and the condensed water can be discharged in the vicinity of the wireless slag or the like, or from the periphery. Further, the auxiliary drain pan functions by the lower space of the heat exchanger for heating which is erected thereon. In the above, the auxiliary drain pan is connected to the bottom of the heat exchange area before the suction side heat exchange area. The auxiliary drain pan is connected to the bottom of the suction-side heat exchange region of the heat exchange region, and the water can enter through the auxiliary drain pan and the condensate drain pan even if water enters for some reason on the side of the suction-exhaust side heat exchange region. drain. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a side view showing an air conditioning unit according to an embodiment of the present invention installed in a drum type washing and drying machine. Fig. 2 is a rear view showing the arrangement of an air conditioning unit according to an embodiment of the present invention in a drum type washing and drying machine. Fig. 3 is a cross-sectional view showing an air-conditioning fan unit in which an air-conditioning unit according to an embodiment of the present invention is connected to a blower fan. Fig. 4 is a cross-sectional view showing a storage area of a compressor of an air conditioning unit according to an embodiment of the present invention and a rear side region which is a part of the air passage. Fig. 5 is a cross-sectional view showing a heat exchange region of an air conditioning unit according to an embodiment of the present invention. Fig. 6 is a plan view showing the air conditioning unit of the embodiment of the present invention with the dividing member on the unit casing removed. Fig. 7 is a perspective view of the air conditioning unit according to the embodiment of the present invention as seen from the oblique side in the state of Fig. 6. 7 201011138 Fig. 8 is a perspective view showing the appearance of an air conditioner according to an embodiment of the present invention as seen from the front side. Fig. 9 is a plan view showing an air conditioning unit according to an embodiment of the present invention as seen from the upper portion. ^ Figure 10 is a plan view of the unit cover of the cut-off member. n Figure 11 is a perspective view of the split member below the 10th figure. Fig. I2 is a lower surface of the dividing member on the unit-like cover of the air conditioning unit according to the embodiment of the present invention. 73 / Fig. 13 is a perspective view showing a state in which the compressor and the elastic seat body of the air conditioning unit according to the embodiment of the present invention are combined. Fig. 14 is a partial perspective view of the embodiment and the unit of the present invention as seen obliquely from the suction discharge side in the state of Fig. 6. Fig. 15 is a side view of the air conditioner unit of the embodiment of the present invention as seen from the side of the housing area. [Heart" Square Package] The best mode for carrying out the invention The air-conditioning fan unit according to the embodiment of the present invention will be described below with reference to Figs. 1 to 15 for the understanding of the present invention. The following description is a specific example of the invention, and is not intended to limit the scope of the patent application. Fig. 1 and Fig. 2 show an air conditioner unit according to an embodiment of the present invention installed in a drum type washing and drying machine. In the first and second figures, the drum type washing and drying machine j is incorporated in the washing and drying machine main body 44, and the water tank 3 is placed in a floating state in a suspended structure (not shown), and is formed in the water tank 3. The bottomed cylindrical rotating drum 2 8 201011138 is arranged such that its axial direction is inclined downward from the front side toward the back side. On the front side of the water tank 3', a garment leading to the open end of the rotary drum 2 is formed. By Xiao Qi, the opening portion of the upwardly inclined surface formed on the front side of the washing machine body 44 is switchably The closing door 9 is rotated by the above-mentioned clothing entrance and exit u, and the laundry is taken out and placed in the cylinder 2. Since the door 9 is disposed on the upwardly inclined surface, the operation of taking out the laundry can be performed without bending. A plurality of through holes φ 8 ' are formed in the circumferential surface of the rotary drum 2 to the inside of the water tank 3, and a feeding projection (not shown) is provided at a plurality of positions in the circumferential direction of the inner circumferential surface. This rotary drum 2 is rotationally driven in the normal rotation direction and the direction of the motor 7 attached to the back side of the water tank 3. Further, the water supply pipe 12 and the drain pipe 12 are connected to the water tank 3 to perform water injection and drainage into the water tank 3 under the control of the water injection valve and the drain valve. .· Open H9 ’ will wash and wash the rider into the rotating drum 2 to set it in the drum type washing and drying machine! The operation of the operation panel on the front surface is controlled by the control of the control substrate 67, which is also provided on the inner side, and the operation is started. In the water tank 3, a predetermined amount of water is injected from the water injection pipe 12, and the motor is rotationally driven. Turn the drum 2 to start the washing step. The washing object accommodated in the rotary drum 2 is repeatedly rotated by the rotary 2' of the rotary drum 2 so that the lion projection provided on the inner peripheral wall of the rotary roller is lifted up to the rotational direction, and is appropriately lifted and lowered. Therefore, the effect of rinsing plays on the laundry, and the washing is performed. After the desired return time, the washing of (10) is discharged from the drain passage 13 'to rotate the rotating drum 2 at a high speed, and the washing liquid contained in the laundry is dehydrated', and then water is injected from the water filling pipe 12 to the water tank 3. Inside, perform the scrubbing step. In this washing step, the laundry 201011138 accommodated in the rotary drum 2 is suspected of rotating the drum 2; $疋 is rotated, and the stirring operation is performed repeatedly by the lifting of the mixing protrusion and being lifted, and the washing is performed. The drum type washing and drying machine 1 is provided with a washing agent contained in the rotary drum 2. Therefore, the material type laundry dryer is as described above, the inner air conditioner fan unit 39, and the air in the water tank 3 is sucked and exhausted, and is introduced into the industrial fan single S39, and the high temperature air for dehumidification, heating and drying is sent to the water tank. The circulating air supply path 5 in the 3 is provided with a blower fan 15 downstream of the air-conditioning fan unit 39 in the circulating air supply path 5. When S is rotationally driven by the blower fan 15, the flow of the idle rolling occurs in the circulating air supply path 5, and the air in the rotating rotary drum 2 is accommodated through the through hole 8' to the circulating air guide from the side of the water tank 3 to the side of the blower fan 15. The human pipeline (10) is exhausted. The humid air of the exhaust gas is condensed from the suction guiding population 391 to the ventilation path of the empty fan unit % directly connected to the upstream side of the air blowing fan 15, and the evaporation in the air||31 condenses the moisture in the air. While dehumidifying and heating by heat exchange with the condensed H32, the dried two-temperature air is sucked to the blower fan b via the suction discharge port 392, and then sent to the air supply duct 33 of the water tank 3, and is blown to the air. Inside the sink 3. The high-temperature dry air that has been blown into the water tank 3 enters the rotary drum 2 through the through-hole 8, and contacts the laundry such as clothes, and then enters the water tank 3, and is again introduced into the circulating air guide line 16 to circulate the air supply path. Repeat the cycle of the air of 5 and perform the drying step. Further, in the drying step A by the circulating air supply path 5, in the air of the circulating air supply path of 5 cycles, foreign matter such as a line method generated by washings such as clothing is mixed and circulated, and the evaporator 31 or the condenser 32 is clogged. The biting into the rotating portion of the blower fan 15 at 201011138, and the accumulation on the inner surface of the blower fan 15 easily hinders the execution of the drying step, and frequently requires complicated maintenance, so generally on the way of the circulating air supply path 5, specifically the evaporator 31 The condenser 32 and the upstream side of the blower fan 15 are provided with a filter 35 for accommodating foreign matter in the circulating air to be stored in the middle of the circulating air introduction line 16. Thereby, even if the foreign matter is mixed into the air which has dried the washing material, it is introduced to the side of the circulating air introduction line 16 on the side of the evaporator 31, and when it passes through the filter chamber, it is trapped by the filter 35, and The circulating air mixed into the downstream side. Therefore, the functions of the evaporator 31, the condenser 32, and the blower fan 15 can be maintained for a long period of time. On the other hand, on the other hand, the trapped foreign matter accumulates in the filter 35 of the filter chamber 36, the passage resistance of the circulating air is gradually increased, and the drying function is lowered, so that the filter 35 is detachably provided in the same manner as usual. Further, the air-conditioning fan unit is directly connected to the air-sending fan 15, and is configured to process the air-conditioning fan unit 81 in a single unit, but is not limited thereto. Here, the evaporator 31 which generates the condensed water together with the condenser 32 constitutes the hot parent changing portion 395, and the storage portion 63 of the condensed water is provided in the range corresponding to the bottom dehumidifying region of the air-conditioning case 38, and the drain having the drain pump 64 is connected. The pipeline is illusory, and appropriate drainage is performed on the basis of the water level detection of the water level sensor not shown. However, due to some drainage abnormalities, when the water level rises abnormally, there is a possibility that the stored condensed water reaches the other part of the circulating air supply path 5. Therefore, the heat exchange portion is disposed at the lowest portion of the circulating air supply path 5. As described above, the air-conditioning fan unit buckle that is used in various types of machines has an impact on the size of the equipment to be mounted, the price of the product, the maintenance time, and the running cost. Therefore, it is expected to be miniaturized, the number of parts, and the number of assembly work are reduced. ^ 11 201011138 Replacement of replacement parts. * A cross-sectional view of an air-conditioning unit connected to a blower fan unit according to an embodiment of the present invention. Fig. 4 is a cross-sectional view showing a storage area of a Qiu Eryi compressor and a partition therewith as a rear portion of the air passage opening nTM end side. Figure 5 is a cross-sectional view of the heat exchange area of the present invention. 6th_unloading unit > cutting member to view the level of the air conditioning unit according to the embodiment of the present invention
面圖。^圖係在第6圖之狀態下從斜方觀看本發明實施形 態之空調單元之立體圖。Surface map. Fig. 6 is a perspective view of the air conditioning unit of the embodiment of the present invention viewed from an oblique side in the state of Fig. 6.
在第3圖〜第7圖中,本實卿態之空調單元39係在且 有吸引導入口 391及吸引排出口 392之單元殼罩38内,内設 有由位於吸引導入口 391至吸引排出口 392之通風路徑393 途中’將循環空氣除濕加熱之蒸發器31及冷凝㈣構成之 熱父換部395與使冷媒在此熱交換部395循環之壓縮機η的 基本結構中,單元殼罩38由複數、具體為上下2個分割構件 381、382構成,以各分割構件381、382於與單元殼罩邛外 面相臨而構成之割線383間連續夾持密封構件384,使單元 殼罩38内外氣密,於以單元殼罩38之前述貯存部63代表之 積水部外部設置以積水開啟,排出積水,阻止外部空氣之 吸引之排水機構1〇1(參照第4圖、第5圖)。 如此,單元殼罩38以複數分割構件381、382構成,以 各分割構件381、382在與單元殼罩38之外面相臨而構成之 割線383間夾持密封材384,使單元殼罩38之内外氣密之簡 單密封構造,即使吸引導入口 391至吸引排出口 392之通風 12 201011138 路徑393有與壓縮機37之收容區域394側之連通,吸引作用 亦不積極地作用’而無形成空氣滯留之收容區域394之影 響’可確保吸引控制之循環與除濕及加熱之功能。又,利 用通風路徑393及收容區域394相互之連通,無收容區域 394、通風路徑393之分別,萬一突然有積水,藉設置於單 70殼罩38之貯存部63等之排水機構1〇1以積水開啟,而排出 積水來因應,並且確保阻止外部空氣之吸引,而導入循環 二氣’將之熱交換而排出之功能。 結果,正因密封處較習知少,而減低零件件數、組裝 工數及零件更換數,故製品成本及運轉費用同時減低。特 別疋如本實施形態般,單元殼罩38以2個分割構件381、382 構成時,可進一步減低零件件數、組裝工數、密封構造部。 如此,藉無密封構造,在通風路徑393,例如與收容區 域394側之連通在雙方之劃分部,此劃分效果合一,吸引作 用歲乎無法及於收容區域394 ’而可更確實地破保吸引空氣 之循環與除濕及加熱之功能,而可提高性能。劃分部386以 一體形成於上下各分割構件391、382兩者之上下劃分壁 386a、386b之相對構造進行,以2構件之簡單結構實現單元 殼罩38劃分收容區域394、通風路徑393而具有之複雜空間 形狀體。且亦可於上下分割構件381、382其中一者一體形 成之單體劃分壁作為劃分部386而取代劃分壁386a、386b。 閥機構101為設置於貯存部63等貯水部外壁之排水口 101a及將此排水口 l〇la以單元殼罩38内之引壓從外側關閉 之止回閥101b,止回閥i〇ib僅於引壓作用於單元殼罩38内 13 201011138 時,以該引壓將設置於貯存部63等貯水部之外壁之排水口 101a關閉’可以良好氣密性遮斷外部空氣,保全空調單元 39之功能,且若萬-有多量之積水時可以其自身重量推 開而排水’且不運作時,不需特地關閉,而可以無關閉特 性之簡單片式閥片實現(參照第續、第5圖)。具體言之,橡 膠片之止回閥101b可以使-體成形於其上端之鉤部驗彈 性卡合於設置在排水口 101aJl部之安裝孔觀,簡單地裝 設,即使吸引、對應於吸引解除之關閉關閉解除頻繁, 其動作衝程微小’而不致加速麟,祕少成域養之更換 〇 零件。 在本實施形態中,與通風路徑393、394之連通構造相 關,或許有突然之積水到達收容區域394側,因而,對應於 熱父換部395之貯存部63同樣地,將收容區域394之底部作 為積水部396 ’設置閥機構ι〇1。藉此,因通風路徑393、收 合區域394之咼低關係等,一旦到達收容區域394側之積水 無法在通風路徑393側之貯存部63側解決時,亦可於收容區 域394側排水。 第8圖係從前部側觀看本發明實施形態之空調單元之 外觀立體圖。第9圖係從上部觀看本發明實施形態之空調單 兀之外觀平面圖。在第8圖、第9圖中,單元殼罩38呈於長 向一端之頂壁後部設有吸引導入口 391,於另一端之端部壁 設有吸引排出口 392之長方體形狀。壓縮機37收容於單元彀 罩38内一端側之靠近前部之收容區域394,以此收容區域 394、相對於此收容區域394於單元殼罩38内之後部側及另 14 201011138 一端側擴展之通風路徑393、從構成此單元殼罩38之分割構 件381、382兩者延伸,構成劃分部386之上下劃分壁386a、 386b或其中一者延伸之劃分壁劃分者(參照第7圖)。蒸發器 31、冷凝器32將與單元殼罩38之長向相對之劃分部386與端 部壁間之熱交換區域393a分隔為前後吸引導入側及吸引排 出侧而設置。再者,吸引導入口 391高於單元殼罩38之熱交 換區域393a之頂壁,向上開口,且如第4圖、第7圖所示, 平面觀看’從在收容區域394之後部側上重疊之位置以從前 述通風路徑393之熱交換區域393a到達在單元殼罩38一端 側擴張至收容區域394後部之一端側後部區域393b上之尺 寸,設置成體積不擴展至空調殼罩38外側。 通風路徑393具有從吸引導入口 391之基部開口平順地 連接於一端側後部區域393b,將循環空氣引導向下之縱向 彎曲區域393c、使熱交換區域393a之後部吸引導入側以小 於吸導入口 391之高度從此吸引導入口 391往上擴張至空調 殼罩38之另一端側之後部向上擴張區域393d。 藉此,在設置於單元殼罩38之長向一端之頂壁後部之 吸引導入口 391與設置於另一端之端部壁之吸引排出口 392 間,除了在單元殼罩38 —端之前部附近,收容壓縮機37, 以劃分部386劃分之收容區域394外,幾乎完全利用單元殼 罩38之長向之通風路徑393 ’輕易地將循環空氣從吸引導入 口 391吸引、導入,而可順暢地供熱交換部之熱交換, 吸引排出至吸引排出口 392。此時,通風路徑393將從吸引 導入口 391導入之循環空氣如第7圖箭號所示,承接至從收 15 201011138 容區域394旁之熱交換區域393a偏離至單元殼罩38—端側 之一端側後部區域393b、從熱交換區域393a之後部偏離至 上部之後部向上擴張部393d,在作為熱交換區域393a之後 部之吸引導入側合流,亦有助設置於熱交換區域393a之熱 交換部395之蒸發器31、冷凝器32之均等通過阻力之充滿效 果’而可生成不致從後部往前部偏離而均等地通過該等蒸 發器31、冷凝器32所有區域之熱交換流。因而,可提高熱 交換效率提高之空調功能。 此時’因通風路徑393為從吸引導入口 391在平面觀 〇 看’在壓縮機37之收容區域394後部側上重疊之位置幾乎重 疊在通風路徑393之一端側後部區域393b上之大小,藉此, —面提高循環空氣之導入風量,一面縮小往前後寬度小於 吸引導入口 391之一端側後部區域393b之流量,但正因在縱 向彎曲路393c之引導下,不致擾亂或壓損而順暢地導入, 朝向熱交換區域393a之後部吸引導入側,並且,正因受到 前述縮小’導入空氣方可易從吸引導入口 391流入延伸至單 疋殼罩38另一端側之後部向上擴張區域393d侧。結果,可 魯 更促進導入至通風路徑393之循環空氣在熱交換部Μ5之朝 後吸入面395a之均等擴散,而可更提高熱交換效率。又, 在前述縱向彎曲路徑393c,如第4圖所示,藉吸引導入空氣 流向彎曲,可將從伴隨之洗滌物去除之水分或有混入之洗 潔劑成份或者柔軟劑成份離心分離,且在以假想線顯示, 避免與壓縮機37上端之干擾的起伏形狀部393cl亦承受撞 擊分離作用。 16 201011138 在此,如第4圖〜第7圖所示’前述之貯存和係構成 狀二交換區域393a之熱交換部395之平面觀看呈矩形之形 盤39致,承載熱交換部395,朝上開放之盤型熱交換部承載 、393&1而形成。設置於此熱交換部承盤盤393al上而被承 395 、、又換部395係使蒸發器21、冷凝器32相互之散熱片 二、有微小之熱分離間隙(圖中未示)而構成相互形成一體 之單元,藉前述熱分離間隙,使從冷凝器32至蒸發器31之 熱移動抑制在抑制蒸發器31之霜或冰之成長,即使在低外In the third to seventh figures, the air conditioning unit 39 of the present embodiment is provided in the unit casing 38 having the suction introduction port 391 and the suction discharge port 392, and is provided in the suction introduction port 391 to the suction row. The ventilation path 393 of the outlet 392 is in the middle of the basic structure of the compressor 395 which is formed by the evaporator 31 and the condensation (4) of the circulating air dehumidification heating, and the compressor η which circulates the refrigerant in the heat exchange portion 395, the unit casing 38. The plural member, specifically, the upper and lower divided members 381 and 382 are formed, and the sealing members 384 are continuously sandwiched between the dividing lines 383 formed by the respective divided members 381 and 382 adjacent to the outer surface of the unit casing, so that the unit casing 38 is inside and outside. The airtight portion of the water storage portion represented by the storage portion 63 of the unit casing 38 is provided with a drain mechanism 1〇1 (see FIGS. 4 and 5) for opening the water to discharge the water and preventing the suction of the outside air. In this manner, the unit case cover 38 is constituted by the plurality of divided members 381 and 382, and the sealing member 384 is sandwiched between the dicing lines 383 formed by the respective divided members 381 and 382 adjacent to the outer surface of the unit case cover 38, so that the unit case cover 38 is The inner and outer airtight simple sealing structure, even if the ventilation inlet 12 391 to the suction discharge port 392 ventilating 12 201011138 path 393 has communication with the receiving area 394 side of the compressor 37, the suction function does not actively act 'without forming air retention The influence of the containment area 394 ' ensures the function of the cycle of control and dehumidification and heating. Further, the ventilation path 393 and the accommodating area 394 are connected to each other, and there is no accommodating area 394 and ventilating path 393. In the event of sudden water accumulation, the drainage mechanism 1 〇1 provided in the storage portion 63 of the single 70 case 38 is used. The function of opening the water, discharging the accumulated water, and ensuring that the attraction of the outside air is prevented, and introducing the circulating two-gas to exchange heat. As a result, the number of parts, the number of assemblies, and the number of parts to be replaced are reduced due to the fact that the number of parts is reduced, so that the product cost and the running cost are simultaneously reduced. In particular, when the unit casing 38 is composed of two divided members 381 and 382 as in the present embodiment, the number of components, the number of components, and the seal structure portion can be further reduced. In this way, by the unsealed structure, the ventilation path 393, for example, communicates with the side of the accommodating area 394 at the division of both sides, and the division effect is unified, and the suction effect is too long to be accommodated in the accommodating area 394'. It attracts air circulation and dehumidification and heating functions to improve performance. The partitioning portion 386 is formed integrally with the opposing partition walls 386a and 386b formed on both the upper and lower divided members 391 and 382. The unit casing 38 is configured to divide the receiving region 394 and the ventilation passage 393 with a simple structure of two members. Complex space shape body. Further, instead of the partition walls 386a and 386b, a single partition wall integrally formed by one of the upper and lower divided members 381 and 382 may be used as the partitioning portion 386. The valve mechanism 101 is a drain port 101a provided on the outer wall of the water storage portion such as the storage portion 63, and a check valve 101b for closing the drain port l〇la from the outside by the pressure in the unit casing 38. The check valve i〇ib is only When the pressure is applied to the inner cover 13 of the unit casing cover 38 201011138, the drain port 101a provided on the outer wall of the water storage portion such as the storage portion 63 is closed by the pressing, so that the outside air can be blocked with good airtightness, and the air conditioning unit 39 is secured. Function, and if there is a large amount of water, it can be pushed away by its own weight and drained', and it does not need to be closed when it is not working. It can be realized by a simple chip valve without closing characteristics (refer to Continued, Figure 5). ). Specifically, the check valve 101b of the rubber sheet can elastically engage the hook portion formed at the upper end of the rubber sheet to the mounting hole provided in the drain port 101aJ1, and is simply installed even if attracted, corresponding to the suction release. The closing and closing are relieved frequently, and the stroke of the action is small 'not to accelerate the Lin, and the secret is replaced by the domain. In the present embodiment, in connection with the communication structure of the ventilation paths 393 and 394, there is a possibility that the sudden accumulation of water reaches the side of the accommodation area 394. Therefore, the storage portion 63 corresponding to the hot parent replacement portion 395 similarly places the bottom of the accommodation area 394. The valve mechanism ι〇1 is provided as the water reservoir 396'. By this means, when the water reaching the storage area 394 side cannot be resolved on the side of the storage portion 63 on the side of the ventilation path 393, the water can be drained on the side of the storage area 394 by the relationship between the ventilation path 393 and the contraction area 394. Fig. 8 is a perspective view showing the appearance of an air conditioning unit according to an embodiment of the present invention as seen from the front side. Fig. 9 is a plan view showing the appearance of an air conditioner unit according to an embodiment of the present invention from the upper portion. In Figs. 8 and 9, the unit case cover 38 is provided with a suction introduction port 391 at the rear end of the top end of the one end and a rectangular parallelepiped shape of the suction port 392 at the end wall of the other end. The compressor 37 is housed in a receiving region 394 on the one end side of the unit cover 38 near the front portion, and the receiving portion 394 is extended with respect to the receiving portion 394 on the rear side of the unit casing 38 and the other end of the 201011138 side. The ventilation path 393 extends from both of the divided members 381, 382 constituting the unit casing 38, and constitutes a partition wall 386a, 386b or a dividing wall divider extending one of the partitioning portions 386 (refer to Fig. 7). The evaporator 31 and the condenser 32 are provided to partition the heat exchange area 393a between the partition portion 386 facing the longitudinal direction of the unit casing 38 and the end wall into a front-rear suction introduction side and a suction discharge side. Further, the suction introduction port 391 is higher than the top wall of the heat exchange region 393a of the unit case 38, and is opened upward, and as shown in Figs. 4 and 7, the plane view 'overlaps from the rear side of the housing area 394. The position is extended from the heat exchange area 393a of the aforementioned ventilation path 393 to the one end side rear area 393b of the rear side of the housing area 394 to the outer side of the air conditioning case 38. The ventilation path 393 has a base opening from the suction introduction port 391 which is smoothly connected to the one end side rear region 393b, guides the circulating air to the downward longitudinal bending region 393c, and causes the heat exchange region 393a rear portion to be attracted to the introduction side to be smaller than the suction introduction port 391. The height of the suction inlet 391 is expanded upward from the suction inlet 391 to the rearward expansion region 393d of the other end side of the air-conditioning case 38. Thereby, between the suction introduction port 391 provided at the rear end portion of the top end of the unit casing cover 38 and the suction discharge port 392 of the end wall wall provided at the other end, except in the vicinity of the front end of the unit casing cover 38 The compressor 37 is accommodated, and the ventilating path 393' of the unit casing cover 38 is used to easily attract and introduce the circulating air from the suction introduction port 391, and the air can be smoothly and smoothly introduced. The heat exchange of the heat exchange unit is sucked and discharged to the suction discharge port 392. At this time, the circulation path 393 introduces the circulating air introduced from the suction introduction port 391 as indicated by the arrow in FIG. 7 to the heat exchange area 393a adjacent to the receiving area 394 from the receiving area 394a to the end side of the unit casing 38. The one end side rear region 393b, the rear portion from the rear portion of the heat exchange region 393a, and the upper rear portion flare portion 393d merge at the suction introduction side of the rear portion of the heat exchange region 393a, and also contribute to the heat exchange portion provided in the heat exchange region 393a. The equalization of the evaporator 31 and the condenser 32 of the 395 can generate a heat exchange flow that passes through all the regions of the evaporator 31 and the condenser 32 uniformly without deviating from the rear portion toward the front portion by the full effect of the resistance. Therefore, the air conditioning function with improved heat exchange efficiency can be improved. At this time, the position where the ventilation path 393 overlaps the rear side of the accommodation area 394 of the compressor 37 from the suction inlet 391 is almost overlapped on the one end side rear area 393b of the ventilation path 393. In this case, the surface is increased in the amount of air introduced into the circulating air, and the flow rate in the front-rear area 393b which is smaller than the one end of the suction introduction port 391 is reduced, but it is smoothly guided by the longitudinal curved path 393c without disturbing or compressing. In the introduction, the introduction side is attracted to the rear portion of the heat exchange region 393a, and the air can be easily introduced from the suction introduction port 391 to the other end side of the single clamshell cover 38 to the rearward portion 393d side. As a result, the uniform flow of the circulating air introduced into the ventilation path 393 to the rearward suction surface 395a of the heat exchange portion Μ5 can be more advantageously promoted, and the heat exchange efficiency can be further improved. Further, in the longitudinal curved path 393c, as shown in FIG. 4, by introducing the air in the suction direction, the moisture removed from the accompanying laundry or the mixed detergent component or the softener component can be centrifugally separated, and As shown by the imaginary line, the undulating shape portion 393cl which avoids interference with the upper end of the compressor 37 is also subjected to the impact separation. 16 201011138 Here, as shown in FIG. 4 to FIG. 7 , the heat exchange portion 395 of the storage and system configuration second exchange region 393 a is viewed in a rectangular shape, and the heat exchange portion 395 is carried. It is formed by the open disk type heat exchange unit bearing 393 & It is disposed on the heat exchange part retaining disk 393al and is supported by 395, and the changing part 395 is configured to make the evaporator 21 and the condenser 32 mutually heat-dissipating two, and has a slight thermal separation gap (not shown). The units integrally formed with each other, the heat separation from the condenser 32 to the evaporator 31 is suppressed by the heat separation gap, and the growth of frost or ice of the evaporator 31 is suppressed, even at a low level.
部f氣溫度,亦可隨著冷媒之溫度上升,使霜溶解,而確 保两乾燥效率之程度。藉此,因省略習知設置於蒸發器31、 、,器32間之隔離空間,設置空間縮小,而不致全體大型 化,且可因應機器大型化,性能之提高,並且可抑制因吸 引排出口 392侧之隔離空間之空隙造成之旁道通過,將有效 面積保持大面積,提高除濕效率 、加熱效率、乾燥效率, 亦可謀求乾燥噪音之減低。在此,熱分離間隙即使為可將 蒸發器31及冷凝器32個別處理而分離之程度之空間的結 構’性能亦不致大幅降低。 熱交換部395以朝後之吸入面395a及與此相對之空調 殼罩38之熱交換區域393a之吸引導入側後部壁之相對距離 從連接於吸引導入口 3 91之一端侧後部區域3 93 b側朝單元 殼罩38之另一端部側縮小之狀態,在相對於單元殼罩38之 長向形成如第6圓、第7圖所示之傾斜方向配置。藉此,相 對於使熱交換區域393a朝向從一端側後部區域393b側朝吸 引排出口 392形成最短之傾斜方向之第6圖所示之方向A,熱 17 201011138 交換部395之散熱片395C之方向之傾斜角0小於將熱交換 部395配置於㈣殼罩38之長向時。正因此縮小,故通風阻 力進-步減低,且通過熱交換部395之通風分布更均一化。 是故’除濕效率、加熱效率皆進—步提高,而可提高空調 性能、搭載至洗衣烘衣機時之乾燥效率、乾雜能, 靜音。 在此,熱交換部395之設置方向係使熱交換區域挪於 從一端側後部區域393b朝吸弓丨排出口说最短之傾斜方向A 儘量一致為最佳。 第10圖係本發明實施形態空調單元之單元殼罩之下分 割構件之平面圖。第n圖係第_之下分割構件之立體 圖在第10圖、第u圖巾,熱交換區域具有熱交換部 承載盤393al及設置於此之熱交換部395之吸引排出側作為 貯存部63而較低,熱交換部395之吸引空氣導人側較高之單 元双罩38之底部形狀而形成,收容區域394如第4圖所示, 以低於貯存部6 3之狀態具有單元殼罩3 8之底部形狀而形 成藉此可抑制在單元殼罩38之壓縮機37之設置高度, 而可降低重心。 熱义換。卩承載盤393al係將熱交換部395如第3圖所 不’不隔著^器而直立載置來承載,承接蒸發器31之部 伤作為承接在4發器3丨產生之凝結水而排出之凝結水排水 盤21 ’承接熱交換部395之冷凝H32之部份從承接蒸發器32 之卩伤劃/7作為將從伴隨循環空氣之洗務物去除之水分 或有進入循%系統之洗潔劑或者柔軟劑之成份在通過熱交 18 201011138 換部395前分離而承接排水之分離水排水盤23,以將兩者分 隔之分隔壁28大致分隔。然而,排水口 22設置於凝結水排 水盤21,分離水排水盤23經由凝結水排水盤21而排出。 此藉循環空氣中之水通過蒸發器31,作為凝結水而去 除’從凝結水排水盤21排出,便無問題。有進入循環空氣 中之黏度高之洗潔劑或柔軟劑之成份進入熱交換部395或 送風扇15時,便附著,而使空氣通路狹窄、堵塞或者提高 送風風扇15之旋轉阻力。是故,於其進入熱交換部395前氣 液分離,從分離水排水盤23經由凝結水排水盤21,在不對 排水泵64造成負擔下排水。此氣液分離當然亦包含伴隨猶 環空氣之水,將已氣液分離之黏性高之洗潔劑或柔軟劑之 成份以同時氣液分離之水洗掉或稀釋,而可不對排水系64 造成負擔而適合。 因此氣液分離,熱交換區域393a之吸引空氣導入侧在 單元殼罩38之下分割構件382中,形成架部24及傾斜部25, s亥架部係從單元殼罩3 8之後部壁大致水平延伸至前部側, 以將從包含一端側後部區域393b之吸引導入口 391及後部 朝上擴張部393d,在熱交換部395之朝後吸入面395a與單元 殼罩38之後部壁間朝下流動之空氣在熱交換部395之第4 圖、第5圖、第7圖所示之高度方向途中位置暫時阻止後, 引導至熱交換部395側,該傾斜部係從此架部24至熱交換部 承載盤393al傾斜至斜下方而連接,將經由架部24之吸引導 入空氣引導而通過設置承載於熱交換部承载盤393al上之 熱交換部395之朝後吸入面395a全面。 19 201011138 藉此,導入至通風路徑393之吸引空氣在從吸引導入口 391及後部朝上擴張部393d朝熱交換部395向下流動之途 中’撞擊架部24 ’而引導至熱交換部395侧。然後,以此撞 擊使從伴隨吸引空氣之洗滌物去除之水分、有進入循環系 統之洗潔劑或柔軟劑之成份從吸引空氣撞擊分離。所分離 之分離水、洗潔劑或柔軟劑之成份亦有吸引空氣之流動, 使架部24移動至傾斜部25側,沿著傾斜部25掉落。具體言 之,分離水一面積極地被沖至傾斜部25側,一面以洗掉黏 I1 生尚之洗潔劑或柔軟劑之成份之形態到達傾斜部側後, 參 除了吸引空氣之流動外,加入重力之作用,沿著傾斜部25 掉落。沿著傾斜部25掉落之分離水等在傾斜部25下部以第5 圖、第11圖所示之肋條26堵住,並且往一端側、圖中所示 / 之例為收容區域34通往前述分離水排水盤23之第3圖、第u . 圖所示之連通路徑27排出,而流人至分離水排水盤23。 另一方面,以熱交換部承載盤393al及吸引排出側構成 射存。卩63全體之底部朝設置於凝結水排水盤Μ之排水口 2咸低、此外’分離水排水盤23於與吸引排出側之分隔壁 φ 八有微j之連通部29a ’於與凝結水排水盤2丨之分隔壁28 、H J之連通部2如。藉此,流入至分離水排水盤Μ之分 等J<由連通部28a ’流入至凝結水排水盤21後,流至位 〆。jc排水盤21之排水口22。又,因連接於排水口Μ之 二水泵:4之動作不良等,一旦溢流至吸引排氣側 ,或有積 、子之水丄由連通部29a,流入至分離水排水盤23後,經由連 通·3 ’流至凝結水排水盤22,到達排水口 22。 20 201011138 連通部28a、29a因應不設置過濾器,而將熱交換部395 設置於熱交換部承載盤393al上,而設定成水可順暢地通 過,線渣或有混入至循環空氣中之黏度高之洗潔劑或柔軟 劑之成份無法直接通過之大小。同樣地,亦於凝結水排水 盤22及分離水排水盤23之流路途中設置不使線渣、洗潔劑 或柔軟劑之成份通過之連通部41及阻擋突起42。即使以此 連通部28a、29a、41、阻檔突起42阻止線渣,其總量仍少, 而不致影響正常排水。反之’所阻止之線屑有助於洗劑成 份之阻止。洗劑成份之阻止阻擂水之通過,而被阻擋之水 積存,同時稀釋洗潔劑’不久已稀釋之洗潔劑往排水口 22 流去。在此,有進入循環空氣之洗潔劑或柔軟劑之成份與 從伴隨循環空氣之洗滌物去除之水份一同通過熱交換部 395前,有效地分離’且在稀釋後排水,故不致對排水泵64 造成負擔,或使其停止。連通部41係將橫切流路之間隔壁 41a之中間部切除成v型而形成,可確實地限制沿底部被沖 之線渣、洗潔劑或柔軟劑之成份之通過,即使被限制通過 之線漬體積稍微增大,而限制水之通過,被限制通過之水 因體積較線渣增加’且連通部41朝上擴展而減低限制度, 而可易與已稀釋之洗劑等之成份一同往前流動。 再者,上述架部24、傾斜部25因使單元殼罩38下半之 後部區域之内部區域縮小,而有效地作用,結果,對單元 Λ又罩38之下半之後部壁賦與往内側凹陷之第4圖、第7圖所 示之凹陷形狀,而在架部24下形成於後方及下方開放之空 的空間S。此空的空間S於空調單元39或空調風扇單元以如 21 201011138 第1圖所示,於洗衣機本體44之底部上沿後部壁設置時,如 第1圖、第4圖所示,可有效利用作為在空調單元39或空調 風扇單元81之外圍進行之配線之結線空間、感測器等外部 機器之設置空間等。 此外,架部24及傾斜部25在下部分割構件382之側一體 形成,易確保其連續性,架部24形成於比在下部分割構件 382之與上部分割構件38丨間構成割線383而接合之接合凸 緣382a略低之位置。接合凸緣382a於其全周之凹條内收容 環狀岔封構件384,以上部分割構件381之接合凸緣381a之 參 凸條敗入至前述凹條之凹凸嵌合夾持密封構件384之接合 構造,进封割線383間。此接合及密封係將接合凸緣Mia、 382a如第11圖所示,以利用設置於圓周方向之複數個鎖固 _ 孔之第3圖所示之螺絲鎖固部68保持穩固。 在此,熱交換部395在收容區域側394,於通風路徑393 與收容區域394之劃分部386如第3圖、第4圖所示,上下夹 持嵌入於形成在上下分割構件381、382間之開口51的端部 具有第4圖、第6圖、第7圖所示於前後突出之金屬板、例如 〇 鋁系等耐蝕性高之分隔壁52,此分隔壁52藉從上方***至 形成於開口 51之口緣、特別是縱向口緣之引導溝,構成 在收容區域394側端部側定位,且抑制通風路徑393與收容 區域394之開口 51部份之通氣之粗略密封構造。又,熱交換 部395之反側之端部、亦即吸引排出口 392側之端部從上方 粗略地嵌入至朝上一體形成於第6圖、第1〇圖所示之下分割 構件382之熱父換部承載盤393al之吸引排出口所側端部 22 201011138 之前後角部的導件53a、53b間而定位。藉該等兩端部之定 位,熱交換部395定位於熱交換部承載盤393al上之預定位置。 第12圖係本發明實施形態空調單元之單元殼罩之上分 割構件之下面圖。在第12圖中,熱交換部395藉從劃分壁 386a至與其相對之另一端部壁間向下形成之肋條狀分隔壁 54抵接上分割構件381之頂壁裡面,而與劃分部386之開口 51之上部口緣共同運作,防止熱交換部395從熱交換部承載 盤393al浮出。同時,防止在熱交換區域393a,吸引導入側 之吸引導入空氣從熱交換部395周圍旁通至吸引排出側。 壓縮機37藉由彈性座體43定位在收容區域394之底部 394c之凹部394a内,而可彈性支撐、緩衝及吸振。藉此種 結構,可謀求壓縮機37本身之小型化、輕量化、低成本化。 又,以藉由彈性座體43定位在凹部394a所作之彈性支撐對 壓縮機37之振動發揮吸振作用,且對脫水時之橫向之外部 振動等亦發揮咼緩衝作用。舉例言之,壓縮機37習知平面 觀看為140mm左右之大體積,而因縮小至9〇mm左右,收容 區域394之必要空間縮小,故單元殼罩38以如習知般之大 小,使通風路徑393及設置於其之熱交換部395增大,提高 熱交換效率’而提高空調性能。 第13圖係顯示内設於本發明實施形態空調單元之壓縮 機與彈性座體之組合狀態之立體圖。在第13圖中使壓縮 機37於蓋在其下部之彈性座體43(參照第3圖)具有徑向之小 間隙而定位,並且使從單元殼罩38之上分割構件381之上部 如第3圖、第12圖所示,向下突出之突起145在壓縮機”之 23 201011138 上端以第3圖所示之預定間隙46相對,而防止從壓縮機37之 凹部394a,超過容許量而脫落。具體言之,間隙45為〇 5111111 左右,間隙46為5mm左右。在此,脫落之容許量為無損對 壓縮機37之吸振、緩衝作用之範圍。 藉此,壓縮機37以自身重量使彈性座體43壓縮至與彈 性座體43之彈性支撐力平衡為止,而在凹部394a内穩定, 在收容區域394内’於徑方向及上下方向具有些微之間隙而 浮動支撐。如第3圖、第5圖、第13圖所示,彈性座體幻具 有與壓縮機37之下面外周區域相對而彈性支撐之環狀卿部 ^ 43a ’而非單純結構,而提高對壓縮機37之振動之吸振性。 再者,腳部43a之下端嵌入至在凹部394a内同心且淺之第2 凹部394b,受到本身半徑方向之移動之限制,在下端部提 高對壓縮機37之徑方向之支撐力,並且可稍微容許壓縮機 37之腳部43a為中心之搖動在前述間隙45之範圍。再者,如 第3圖、第6圖、第13圖所示,彈性座體43具有連接於腳部 43a之上端,以略厚之厚度覆蓋於壓縮機37之下部外周之蓋 部43b’當前述壓縮機37之搖動於某個特定徑方向超過前述 Ο 間隙45時,亦可在與凹部394a内周之間,於蓋部43b對應之 特定徑方向壓縮’故可發揮對振動般之搖動之吸振作用, 可減低振動傳達至單元殼罩38時之撞擊音。蓋部43b藉在其 外周’軸線方向之肋條43 c配設於圓周方向,而可彈性且適 度地執行在與前述凹部394a内周之間之壓縮所作之吸振, 而可將壓縮機37彈性支撐為位於凹部394a内之預定範圍 内。又,蓋部43b於其周壁形成與從壓縮機37突出至本體部 24 201011138 側邊之配管-部份等卡合之卡合凹料,形㈣性座體43 與壓縮機37之防止旋轉結構。亦可於彈性座體43與凹部 394a間設置防止旋轉之卡合部或嵌合部。又,亦可使彈性 座體43之腳部43a與蓋部43b等部份為分開之構件。總之, 以彈性構件練凹部394a與壓賴37之下端部間之空間為基 本條件。 收容區域394如第3圖所示,將形成有凹部徽之底部 394c設定成稍高於熱交換部承載盤393&1及吸引排出側 393a2之底部,在以劃分部386夾持熱交換部395之開口湖 圍劃分收容區域394側與通風路393側,於開口 51口緣之下 部設置凹條,將收容區域394側連接於通風路徑393側之分 離水排水盤23,具體言之,藉由連通路肋來連接,將連 通路徑47形成於底部394c之熱交換部395下。此外,於底部 州牝形成使凹部394a之内周壁延長至上方,如第3圖、第 圖、第6圖、第1〇圖所示之環狀肋條48。再者,前述底部别 之-部份對應於壓縮機37周圍之低溫配管37&之凝結水滴 下部’阻止滴下之凝結水。結果’從低溫配管%在運轉中 以少量而穩定地滴下之凝結水為凹部⑽之底部咖 所阻止,於劃分部386之開口51之開口緣下部,通過以與底 部394c相同之水平形成之連通路徑47,流動㈣至低於底 —π 鬥曰热地排出 凹部39袖為祕简邮,㈣㈣人。由於使壓 37定位之凹部394a*需排水孔,可減排水路徑 引外部空氣’故不致使低溫時之乾燥效率降低。 25 201011138 如前述’以熱交換部395之對單元殼罩38之長向之斜向 配置’從下游之送風風扇15到達吸引排出口392之吸引作用 對朝向熱交換部3 95前部之排出面3 95 b仍是照常在靠近吸 引排出口392之側強力運作。因此,在熱交換區域393a之吸 引排出側,有從接近熱交換部395之朝前排出面395b之吸引 排出口392之側通過蒸發器31時產生之凝結水吸出至排出 面395b側,通過吸引排出口 392,吸入至送風風扇15之虞。 第14圖係在第6圖之狀態下從吸引排出側斜上觀看本 發明實施形態空調單元之部份立體圖。第15圖係從收容區 參 域側觀看本發明實施形態之空調單元之側面圖。在第14 圖,在本實施形態中,利用在熱交換部承載盤393al之吸引 排出口392側端部之前部側,延伸至上方之導件53a,形成 / 阻擋吸引排出口 392之強力吸引作用之凝結水之吸引的遮 : 蔽壁56。又,在第15圖,此強力吸引作用之係以連接於吸 引排出口 392之送風風扇15具有螺形殼15b,其吹出部 15d(參照第12圖)在後部朝上直立之位置關係設置,作為沿 +务 編| 者熱父換部395之排出面395b之吸引排出口 392側端緣之下 半部與下端緣之前部側之角部,因應此,遮蔽壁56如第3 圖、第8圖、第11圖所示,可以包含導件53a,形成階梯狀 之單純形狀將熱交換部395之排出面395b覆蓋必要最小限度。 階梯狀遮蔽壁56相對於吸引力強力作用於冷凝器32之 吸引排出口 392侧之端部、特別是下部,下部形成使從側邊 往排出面395b側之突出量大於上部之階梯狀。藉此,吸引 排出口 392之吸引在冷凝器32之排出面395b之吸引排出口 26 201011138 側392側之端部、特別是下部增強,朝上部逐漸減弱,因此’ 遮蔽56覆蓋冷凝器32之吸引排出口392側下部大於其上側 部,而可隨 著從冷凝器32之排出面395b之吸引排出口 392強 力傳達之吸引力分布之強弱,適當地地限制吸引。 遮蔽部56亦可具有包含傾斜、彎曲等之突出緣取代階 梯狀,從冷凝器之排出面周邊之下部或側部突出設置,遮 蔽部56從冷凝器32周邊突出至其排出面395b側’阻擋吸引 排出口 392之強力吸引,而其突出緣呈傾斜、彎曲、階梯任 一形狀。藉此,遮蔽壁56突出至冷凝器32之排出面395b侧, 與阻擋吸引排出口 392之強力吸引之程度成比例之突出量 易配合強力吸引之強弱分佈,而可形成更適當之限制。 又,為使遮蔽壁56儘量不縮小排出面395b之通風面 積,使導件53a之突出部56a從排出面395b如第6圖所示浮 出,而形成間隙111。如此,遮蔽壁56突出至冷凝器32之排 出面395b側,覆蓋吸引排出口 392之強力吸引,限制吸引排 出口 392之強力吸引。然而,因於與排出面395b間具有間隙 111,故吸引排出口 392之吸引繞入間隙而到達,故不致在 遮蔽壁56覆蓋冷凝器32之範圍,阻止通風,而無法發揮功 能。因而,可避免縮小冷凝器32之作用區域,性能降低。 特別是,藉遮蔽壁56所作之強力吸引之限制度與間隙lu之 繞入吸引度之平衡,可將冷凝器32全區之熱交換均一化。 再者,在與送風風扇15之風扇15a同心之吸引排出口 392中,其遮蔽壁56之吸入限制侧如第u圖所示,具有縮小 吸引排出口 392之風!15a之輪線周圍之圓形的縱向直線緣 27 201011138 392b’呈突出至軸線側之形狀,易防止熱交換部395之吸引 排出口之水之吸入。同樣地,吸引排出口 392之下緣亦形成 於朝轴線向上縮小至與熱交換部承健39如相同之高度 之橫向直線緣392e ’限制貯存部63底部之水分之吸入。 單元殼罩38之吸引排出口 392與送風風扇15之連接如 第3圖所示’於吸引排出口吹之内周具有間隙,嵌合收容 有風扇以之螺形殻15b之吸弓丨口…之連接筒15c卜又,使 連接筒以1之前端壓接吸弓I排出口 392内周之凸緣壁 392a。設有將螺形殼l5b與空調殼罩⑽在吸引口 15。之連结 · 部周圍複數處、例如3處以上螺固之連結部,保持前述壓接 狀態,簡易地密封連接部。藉此,無作為消耗品之密封構 件,製品成本、成本皆減低。 此外’當單元殼罩38叫gj分漏件構成時,有各成形 . 品容董縮小之優點,也易因應複雜之形狀。應用於圖中所 示之例時’參照第8圖來說明,在第8圖所示之單純水平面 上具有與單元殼罩38外面相臨之割線(二點鏈線)61,而將在 上部分割構件381中,熱交換區域303al之頂壁以下之部 修 份、尚於其之部份、亦即朝上擴張區域393d、吸引導入口 391及收容區域394上部分割,藉由在此割線61間之全周連 續之後封構件,將空調殼罩38内外密封時,可在不破壞2分 割構造之上述實施形態之特點下,獲得以3個分割構件構成 之特點。 根據本發明,可將在空調殼罩内之熱交換區域產生或 積聚之水類在無過濾器下排水,而可不需過濾器及其之保 28 201011138 養。 【圖式簡單說明3 第1圖係本發明實施形態之空調單元裝設於滾筒式洗 衣烘衣機之側面圖。 第2圖係本發明實施形態之空調單元裝設於滾筒式洗 衣烘衣機之背面圖。 第3圖係顯示於本發明實施形態之空調單元連接送風 風扇之空調風扇單元之截面圖。 第4圖係本發明實施形態之空調單元之壓縮機之收容 區域及與其分隔,作為送風通路一部份之一端側後部區域 的橫截面圖。 第5圖係本發明實施形態空調單元之熱交換區域之橫 截面圖。 第6圖係卸除單元殼罩之上分割構件而觀看本發明實 施形態之空調單元之平面圖。 第7圖係在第6圖之狀態下從斜方觀看本發明實施形態 之空調單元之立體圖。 第8圖係從前部側觀看本發明實施形態之空調單元之 外觀立體圖。 第9圖係從上部觀看本發明實施形態之空調單元之外 觀平面圖。 第10圖係本發明實施形態空調單元之單元殼罩之下分 割構件之平面圖。 第11圖係第10圖之下分割構件之立體圖。 29 201011138 第12圖係本發明實施形態空調單元之單元殼罩之上分 割構件之下面圖。 第13圖係顯示内設於本發明實施形態空調單元之壓縮 機與彈性座體之組合狀態之立體圖。 第14圖係在第6圖之狀態下從吸引排出側斜上觀看本 發明實施形態空調單元之部份立體圖。 第15圖係從收容區域側觀看本發明實施形態之空調單 元之側面圖。 【主要元件符號說明】 1...滾筒式洗衣烘衣機 15d...吹出部 2...旋轉滚筒 16...循環空氣導入管路 3…水槽 21…凝結秘水盤 5…循環送風路徑 22...排水口 7...馬達 23…分離水排水盤 8…透孔 24...架部 9…門 25…傾斜部 11."衣類出入口 26,43c,48...肋條 12...注水管路 27…連通離 13...排水管路 28,29...分隔壁 15 …扇 28a,29a...連通部 15a... 31".蒸發器 15b...螺形殼 32···冷凝器 15c...吸引口 33...送風管路 15cl···連接筒 35.··過濾器 30 201011138The f gas temperature can also dissolve the frost as the temperature of the refrigerant rises, ensuring the degree of drying efficiency. By omitting the isolation space provided between the evaporator 31 and the device 32, the installation space is reduced, and the overall size is not increased, and the performance can be increased in response to the increase in size of the machine, and the suction discharge port can be suppressed. The bypass path caused by the gap of the isolation space on the 392 side allows the effective area to be maintained in a large area, and the dehumidification efficiency, the heating efficiency, the drying efficiency, and the drying noise can be reduced. Here, the structure of the space where the thermal separation gap is separated by the degree of separation of the evaporator 31 and the condenser 32 is not greatly reduced. The heat exchange portion 395 is opposed to the suction-introduction side rear wall by the rearward suction surface 395a and the heat exchange region 393a of the air-conditioning case 38, and is connected to one end side rear region 3 93b of the suction introduction port 391. The state in which the other end side of the unit case cover 38 is reduced is formed in an oblique direction as shown in the sixth circle and the seventh figure with respect to the longitudinal direction of the unit case 38. Thereby, the direction of the heat sink 395C of the exchange portion 395 is set to the direction A shown in FIG. 6 in which the heat exchange region 393a is formed in the shortest inclination direction from the one end side rear portion 393b side toward the suction discharge port 392. The inclination angle 0 is smaller than when the heat exchange portion 395 is disposed in the long direction of the (four) casing 38. As a result, the ventilation resistance is further reduced, and the ventilation distribution through the heat exchange portion 395 is more uniform. Therefore, the dehumidification efficiency and the heating efficiency are both improved, and the air conditioning performance can be improved, the drying efficiency when carrying the laundry dryer, the dryness and the miscellaneous energy, and the mute. Here, the direction in which the heat exchange portion 395 is disposed is such that the heat exchange region is preferably moved from the one end side rear portion 393b toward the suction bow discharge port so that the shortest inclination direction A is as uniform as possible. Fig. 10 is a plan view showing a dividing member under the unit casing of the air conditioning unit according to the embodiment of the present invention. The nth image is a perspective view of the _lower divided member. In the 10th and UBth tissues, the heat exchange portion has a heat exchange portion carrying tray 393a1 and a suction discharge side of the heat exchange portion 395 provided therein as the storage portion 63. Lower, the heat exchange portion 395 is formed by the bottom shape of the unit double cover 38 which is higher in the suction air guiding side, and the receiving area 394 has the unit casing 3 in a state lower than the storage portion 63 as shown in FIG. By forming the bottom shape of 8, the height of the compressor 37 of the unit casing 38 can be suppressed, and the center of gravity can be lowered. Hot meaning change. The cymbal tray 393a is configured such that the heat exchange unit 395 is placed upright without being placed across the apparatus as shown in FIG. 3, and the portion of the evaporator 31 is discharged as condensed water generated by the ejector 3 The condensate drain pan 21' receives part of the condensing H32 of the heat exchange portion 395 from the entanglement of the evaporator 32/7 as water removed from the washings accompanying the circulating air or has a wash into the system. The detergent or softener component is separated prior to passing through the heat exchange 18 201011138 change 395 to receive the drained separation water drain pan 23 to substantially separate the partition walls 28 that separate the two. However, the drain port 22 is provided in the condensate drain pan 21, and the split water drain pan 23 is discharged through the condensate drain pan 21. The water in the circulating air passes through the evaporator 31 and is removed as condensed water to be discharged from the condensate drain pan 21 without problems. When the component of the detergent or the softener having a high viscosity entering the circulating air enters the heat exchange portion 395 or the blower fan 15, it adheres to narrow the air passage, block the air, or increase the rotational resistance of the blower fan 15. Therefore, the gas is separated before entering the heat exchange unit 395, and the water is drained from the separation water drain pan 23 via the condensate drain pan 21 without burdening the drain pump 64. The gas-liquid separation of course also includes the water accompanying the air of the yoke ring, and the components of the highly viscous detergent or softener which have been separated by the gas-liquid separation are washed or diluted with the water separated by the gas-liquid separation, but the drainage system is not available. It is suitable for the burden. Therefore, the gas-liquid separation, the suction air introduction side of the heat exchange region 393a is formed in the divided member 382 under the unit casing 38, and the frame portion 24 and the inclined portion 25 are formed, and the s-frame portion is substantially from the rear wall of the unit casing 38. Horizontally extending to the front side so as to be directed from the suction introduction port 391 and the rearward upward expansion portion 393d including the one end side rear region 393b, between the rearward suction surface 395a of the heat exchange portion 395 and the rear wall of the unit casing 38 The air flowing downward is temporarily blocked at the intermediate position in the height direction shown in FIG. 4, FIG. 5, and FIG. 7 of the heat exchange portion 395, and then guided to the heat exchange portion 395 side, and the inclined portion is from the frame portion 24 to the heat. The exchange portion carrying tray 393al is connected obliquely downward and connected, and is guided by the suction introduction air passing through the frame portion 24, and is provided in the entire rearward suction surface 395a of the heat exchange portion 395 provided on the heat exchange portion carrying tray 393al. 19 201011138 Thereby, the suction air introduced into the ventilation path 393 is guided to the heat exchange portion 395 side in the middle of the suction port portion 24' flowing downward from the suction introduction port 391 and the rear portion upward expansion portion 393d toward the heat exchange portion 395. . Then, by this collision, the moisture removed from the laundry accompanying the suction of the air, the detergent or the softener entering the circulation system is separated from the suction air. The components of the separated separated water, detergent or softener also have a flow of suction air, and the frame portion 24 is moved to the inclined portion 25 side and falls along the inclined portion 25. Specifically, the separated water is actively flushed to the side of the inclined portion 25, and after reaching the inclined portion side in the form of washing off the component of the detergent or the softener, it is added to the flow of attracting air, and is added. The action of gravity falls along the inclined portion 25. The separated water or the like falling along the inclined portion 25 is blocked by the ribs 26 shown in Figs. 5 and 11 at the lower portion of the inclined portion 25, and is led to the receiving portion 34 as shown in the figure on the one end side. The communication path 27 shown in Fig. 3 and Fig. 5 of the separated water drain pan 23 is discharged, and flows to the separation water drain pan 23. On the other hand, the heat exchange portion carrying tray 393a1 and the suction discharge side constitute a jet. The bottom of the 卩63 is flushed toward the drain port 2 provided in the condensate drain pan, and the 'separated water drain pan 23 is connected to the partition wall φ8 on the suction and discharge side. For example, the partition wall 28 of the disk 2 and the communication portion 2 of the HJ are as follows. As a result, the J<s> flowing into the separated water drain pan 流入 is flown into the condensate drain pan 21 by the communicating portion 28a', and then flows to the position 〆. Jc drain port 22 of drain pan 21. In addition, the operation of the second water pump: 4 connected to the drain port is insufficient, and if it overflows to the suction exhaust side, or the water is accumulated in the communication portion 29a, it flows into the separation water drain pan 23, and then passes through The connection 3' flows to the condensate drain pan 22 and reaches the drain port 22. 20 201011138 The communication portions 28a and 29a are disposed on the heat exchange portion carrier plate 393al without providing a filter, and are set so that water can smoothly pass, and the line slag or the viscosity mixed into the circulating air is high. The ingredients of the detergent or softener cannot pass directly through the size. Similarly, the communication portion 41 and the blocking projection 42 that do not pass the components of the slag, the detergent or the softener are provided in the flow path of the condensate drain pan 22 and the separation water drain pan 23. Even if the connecting portions 28a, 29a, 41 and the blocking projections 42 block the slag, the total amount thereof is small, so that the normal drainage is not affected. Conversely, the swarf that is prevented helps to prevent the ingredients from being washed. The ingredients of the lotion prevent the passage of the blocked water, and the blocked water accumulates while diluting the detergent. The diluted detergent is then drained to the drain port 22. Here, the ingredients of the detergent or softener which enter the circulating air are effectively separated from the water removed from the washing accompanying the circulating air, and are drained after dilution, so that the drainage is not caused. Pump 64 causes a load or stops it. The communicating portion 41 is formed by cutting the intermediate portion of the partition wall 41a across the flow path into a v-shape, and can surely restrict the passage of the components of the line slag, the detergent or the softener which are washed along the bottom, even if it is restricted. The volume of the line stain is slightly increased, and the passage of water is restricted, the water that is restricted is increased by the volume of the slag, and the connecting portion 41 is expanded upward to reduce the limit, and the ingredients such as the diluted lotion can be easily replaced. Flow forward together. Further, the frame portion 24 and the inclined portion 25 are effectively actuated by reducing the inner region of the lower half of the unit casing cover 38. As a result, the unit Λ and the lower half of the cover 38 are provided to the inner side. The concave shape shown in Figs. 4 and 7 of the recess is formed in the space S which is open to the rear and the lower side under the frame portion 24. This empty space S can be effectively utilized as shown in FIG. 1 and FIG. 4 when the air conditioning unit 39 or the air-conditioning fan unit is disposed along the rear wall on the bottom of the washing machine body 44 as shown in FIG. 1 of FIG. 21 201011138. The wiring space of the wiring performed on the periphery of the air conditioning unit 39 or the air-conditioning fan unit 81, the installation space of an external device such as a sensor, and the like. Further, the frame portion 24 and the inclined portion 25 are integrally formed on the side of the lower divided member 382, and the continuity thereof is easily ensured. The frame portion 24 is formed to be joined to the upper divided member 38 by the secant line 383 between the lower divided member 382 and the lower divided member 38. The joint flange 382a is slightly lower. The joint flange 382a accommodates the annular seal member 384 in the entire circumference of the recess, and the engagement rib of the joint flange 381a of the upper divided member 381 is broken into the joint structure of the concave-convex fitting and clamping seal member 384 of the concave strip. , enter the secant line 383. This joining and sealing system holds the engaging flanges Mia, 382a as shown in Fig. 11 and is held stationary by the screw locking portions 68 shown in Fig. 3 of a plurality of locking holes provided in the circumferential direction. Here, the heat exchange unit 395 is sandwiched between the upper and lower divided members 381 and 382 in the partitioning portion 394 of the ventilation passage 393 and the housing region 394 as shown in Figs. 3 and 4, as shown in Figs. 3 and 4, respectively. The end portion of the opening 51 has a metal plate protruding forward and backward as shown in Figs. 4, 6, and 7, and a partition wall 52 having high corrosion resistance such as a bismuth aluminum alloy, and the partition wall 52 is inserted into the upper portion. The guide groove of the opening 51, particularly the longitudinal rim, is formed to be positioned on the end side of the housing area 394, and the rough sealing structure of the ventilation passage 393 and the opening 51 of the housing area 394 is suppressed. Further, the end portion on the opposite side of the heat exchange portion 395, that is, the end portion on the side of the suction discharge port 392 is roughly fitted from above to the partition member 382 which is integrally formed on the lower side as shown in Fig. 6 and Fig. 1 . The hot-female replacement portion carrier 393a is positioned between the suction end portion side end portion 22 201011138 and the front corner portion guide members 53a, 53b. The heat exchange portion 395 is positioned at a predetermined position on the heat exchange portion carrying tray 393al by the positioning of the both end portions. Fig. 12 is a bottom view of the dividing member on the unit casing of the air conditioning unit according to the embodiment of the present invention. In Fig. 12, the heat exchange portion 395 abuts against the inside of the top wall of the upper divided member 381 by the rib-shaped partition wall 54 formed between the partition wall 386a and the other end wall opposite thereto, and the partition portion 386 The upper edge of the opening 51 operates in unison to prevent the heat exchange portion 395 from floating from the heat exchange portion carrying tray 393al. At the same time, in the heat exchange region 393a, the suction introduction air on the suction introduction side is prevented from bypassing from the periphery of the heat exchange portion 395 to the suction discharge side. The compressor 37 is positioned in the recess 394a of the bottom portion 394c of the receiving area 394 by the elastic seat 43, and is elastically supported, cushioned, and absorbing. With this configuration, it is possible to reduce the size, weight, and cost of the compressor 37 itself. Further, the elastic support by the elastic seat 43 positioned in the concave portion 394a exerts a vibration absorbing effect on the vibration of the compressor 37, and also acts as a buffer for external vibration in the lateral direction during dehydration. For example, the compressor 37 is conventionally viewed as having a large volume of about 140 mm, and since it is reduced to about 9 mm, the necessary space of the receiving area 394 is reduced, so that the unit casing 38 is sized as is conventionally known. The path 393 and the heat exchange portion 395 provided therein are increased to improve the heat exchange efficiency' to improve the air conditioning performance. Fig. 13 is a perspective view showing a combined state of a compressor and an elastic seat provided in an air conditioning unit according to an embodiment of the present invention. In Fig. 13, the compressor 37 is positioned with a small radial gap in the elastic seat 43 (refer to Fig. 3) which is covered at the lower portion thereof, and the upper portion of the dividing member 381 from the unit casing 38 is as described above. As shown in Fig. 12 and Fig. 12, the downwardly projecting projection 145 is opposed to the predetermined gap 46 shown in Fig. 3 at the upper end of the compressor 23, 201011138, and is prevented from falling out of the recess 394a of the compressor 37 beyond the allowable amount. Specifically, the gap 45 is about 1115111111, and the gap 46 is about 5 mm. Here, the allowable amount of detachment is a range that does not impair the vibration absorption and buffering action of the compressor 37. Thereby, the compressor 37 makes elasticity by its own weight. The seat body 43 is compressed until it is balanced with the elastic supporting force of the elastic seat body 43, and is stabilized in the recessed portion 394a, and has a slight gap in the radial direction and the vertical direction in the receiving region 394 to be supported by the floating. As shown in Fig. 3, As shown in Fig. 5 and Fig. 13, the elastic seat body has an annular portion 43a' which is elastically supported opposite to the outer peripheral portion of the compressor 37, and is not a simple structure, thereby improving the vibration absorption of the vibration of the compressor 37. Furthermore, the foot 43a The second recess 394b, which is concentric and shallow in the recess 394a, is restrained by the movement in the radial direction thereof, and the supporting force in the radial direction of the compressor 37 is increased at the lower end portion, and the leg portion of the compressor 37 can be slightly allowed. The centering of 43a is in the range of the aforementioned gap 45. Further, as shown in Fig. 3, Fig. 6, and Fig. 13, the elastic seat body 43 has an upper end connected to the leg portion 43a and is covered with a slightly thick thickness. The cover portion 43b' of the outer periphery of the lower portion of the compressor 37 may also have a specific diameter corresponding to the cover portion 43b between the inner circumference of the concave portion 394a and the inner diameter of the recess portion 394a when the compressor 37 is rocked in a certain specific radial direction. The direction compression is performed so that the vibration absorbing vibration can be exerted, and the impact sound when the vibration is transmitted to the unit casing 38 can be reduced. The cover portion 43b is disposed in the circumferential direction by the rib 43c in the outer circumferential direction The vibration absorption by compression between the inner circumference of the recess 394a can be performed elastically and moderately, and the compressor 37 can be elastically supported to be within a predetermined range within the recess 394a. Further, the cover portion 43b is formed and formed on the peripheral wall thereof. Compressor 37 The anti-rotation structure of the tube-partially-engaged engagement recess, the (four) seat body 43 and the compressor 37 protrudes to the side of the main body portion 24, 201011138. The anti-rotation structure between the elastic seat body 43 and the recess portion 394a can also be prevented. The engaging portion or the fitting portion of the rotating portion. Further, the leg portion 43a of the elastic seat body 43 and the portion of the lid portion 43b may be separate members. In short, the lower end portion of the recessed portion 394a and the pressure relieving portion 37 is formed by the elastic member. The space between the spaces is the basic condition. As shown in Fig. 3, the bottom portion 394c in which the concave portion is formed is set to be slightly higher than the bottom portion of the heat exchange portion carrying tray 393 & 1 and the suction discharge side 393a2. The opening lake of the 386-clamping heat exchange portion 395 divides the side of the receiving area 394 and the side of the air passage 393, and a recess is provided below the opening edge of the opening 51, and the side of the receiving area 394 is connected to the separating water draining tray 23 on the side of the ventilation path 393. Specifically, the communication path 47 is formed under the heat exchange portion 395 of the bottom portion 394c by connecting the communication ribs. Further, in the bottom state, an annular rib 48 is formed which extends the inner peripheral wall of the concave portion 394a upward as shown in Fig. 3, Fig. 6, Fig. 6, and Fig. 1 . Further, the other portion of the bottom portion corresponds to the lower portion of the condensed water droplets of the low temperature piping 37 & around the compressor 37 to prevent the condensed water from dripping. As a result, the condensed water which is stably dropped from the low-temperature piping % in operation is blocked by the bottom portion of the recess (10), and is formed at the lower level of the opening edge of the opening 51 of the dividing portion 386 by the same level as the bottom portion 394c. Path 47, flow (four) to below the bottom - π bucket hot discharge recess 39 sleeves for the secret brief, (four) (four) people. Since the recess 394a* for positioning the pressure 37 requires a drain hole, the water passage can be reduced to introduce external air, so that the drying efficiency at a low temperature is not lowered. 25 201011138 As described above, 'the oblique arrangement of the heat exchange portion 395 to the longitudinal direction of the unit casing 38 is arranged to 'the suction effect from the downstream air supply fan 15 to the suction discharge port 392 to the discharge surface toward the front portion of the heat exchange portion 3 95 3 95 b is still operating as strongly as it is near the suction outlet 392. Therefore, on the suction and discharge side of the heat exchange area 393a, the condensed water generated when passing through the evaporator 31 from the side close to the suction discharge port 392 of the front discharge surface 395b of the heat exchange portion 395 is sucked to the discharge surface 395b side by suction. The discharge port 392 is sucked into the blower fan 15. Fig. 14 is a partial perspective view of the air conditioning unit according to the embodiment of the present invention as seen obliquely from the suction and discharge side in the state of Fig. 6. Fig. 15 is a side view of the air conditioning unit according to the embodiment of the present invention as seen from the side of the receiving area. In the present embodiment, the guide member 53a is extended to the upper side of the end portion of the heat exchange portion carrying tray 393a on the side of the suction discharge port 392, thereby forming/blocking the strong suction of the suction discharge port 392. Concealed by the condensation of condensed water: the wall 56. Further, in Fig. 15, the blower fan 15 connected to the suction discharge port 392 has a screw-shaped case 15b, and the blow-out portion 15d (see Fig. 12) is disposed in a positional relationship in which the rear portion is erected upward. As a corner portion of the lower end portion of the suction port 392 side and the lower end portion of the lower end edge of the discharge surface 395b of the hot-father replacement portion 395, the shielding wall 56 is as shown in FIG. 3, As shown in Fig. 8 and Fig. 11, the guide member 53a may be included, and a simple stepped shape may cover the discharge surface 395b of the heat exchange portion 395 to a minimum. The stepped shielding wall 56 strongly acts on the end portion of the condenser 32 on the suction/discharge port 392 side, particularly the lower portion, with respect to the suction force, and the lower portion is formed in a stepped shape in which the amount of projection from the side to the discharge surface 395b side is larger than that of the upper portion. Thereby, the suction of the suction discharge port 392 is reinforced at the end of the suction discharge port 26 201011138 side 392 side of the discharge surface 395b of the condenser 32, particularly the lower portion, and gradually weakens toward the upper portion, so that the shield 56 covers the suction of the condenser 32. The lower portion of the discharge port 392 is larger than the upper portion thereof, and the suction can be appropriately restricted in accordance with the strength distribution of the attraction force strongly transmitted from the suction discharge port 392 of the discharge surface 395b of the condenser 32. The shielding portion 56 may have a protruding edge including a slope, a curve, or the like instead of a stepped shape, and protrudes from a lower portion or a side portion of the discharge surface of the condenser, and the shielding portion 56 protrudes from the periphery of the condenser 32 to the side of the discharge surface 395b thereof. The suction port 392 is strongly attracted, and its protruding edge is inclined, curved, and stepped in any shape. Thereby, the shielding wall 56 protrudes to the discharge surface 395b side of the condenser 32, and the amount of protrusion which is proportional to the degree of strong attraction of the suction suction discharge port 392 is easily distributed in accordance with the strong attraction force, and a more appropriate restriction can be formed. Further, in order to prevent the shielding wall 56 from shrinking the ventilation area of the discharge surface 395b as much as possible, the protruding portion 56a of the guide 53a is floated from the discharge surface 395b as shown in Fig. 6, thereby forming a gap 111. Thus, the shielding wall 56 protrudes to the side of the discharge surface 395b of the condenser 32, covering the strong suction of the suction discharge port 392, and restricting the strong suction of the suction discharge port 392. However, since there is a gap 111 between the discharge surface 395b and the suction port 392, the suction of the suction port 392 reaches the gap, so that the shield wall 56 does not cover the condenser 32, and ventilation is prevented, and the function cannot be performed. Thus, it is possible to avoid shrinking the active area of the condenser 32, and the performance is lowered. In particular, the heat exchange between the entire area of the condenser 32 can be uniformized by the restriction of the strong attraction by the shielding wall 56 and the balance of the attraction of the gap lu. Further, in the suction discharge port 392 which is concentric with the fan 15a of the blower fan 15, the suction restricting side of the shield wall 56 has a wind which narrows the suction discharge port 392 as shown in Fig. u! The circular longitudinal straight edge 27 201011138 392b' around the wheel line 15a has a shape protruding to the axial side, and it is easy to prevent the suction of the water at the suction discharge port of the heat exchange portion 395. Similarly, the lower edge of the suction discharge port 392 is also formed by the lateral straight edge 392e' which is narrowed toward the axis to the same height as the heat exchange portion bearing 39 to restrict the suction of the moisture at the bottom of the reservoir portion 63. The connection between the suction discharge port 392 of the unit casing 38 and the blower fan 15 has a gap on the inner circumference of the suction discharge port as shown in Fig. 3, and the suction port of the screw case 15b is fitted and fitted with a fan... The connecting cylinder 15c further presses the connecting cylinder to the flange wall 392a of the inner circumference of the suction port I 392 at the front end of the connecting cylinder. A screw casing 15b and an air conditioner casing (10) are provided at the suction port 15. Connections: A plurality of connection points, for example, three or more screw joints around the portion, maintain the pressure contact state, and easily seal the connection portion. Thereby, there is no sealing member as a consumable product, and the cost and cost of the product are reduced. In addition, when the unit casing cover 38 is called a gj-dividing member, there are various forms. The advantages of the product capacity reduction are also easy to cope with the complicated shape. When applied to the example shown in the figure, it will be described with reference to Fig. 8, which has a secant line (two-point chain line) 61 adjacent to the outer surface of the unit casing 38 on the simple horizontal plane shown in Fig. 8, and will be in the upper portion. In the dividing member 381, the portion of the heat exchange region 303a1 below the top wall of the heat exchange region 303al is divided, that is, the upwardly expanding region 393d, the suction introduction port 391, and the upper portion of the receiving region 394 are divided by the secant line 61. When the air-conditioning case 38 is sealed inside and outside after the entire circumference, the three-part members can be obtained without damaging the two-divided structure. According to the present invention, the water generated or accumulated in the heat exchange area in the air-conditioning casing can be drained without the filter, without the need for the filter and its protection. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view showing an air conditioning unit according to an embodiment of the present invention installed in a drum type washing and drying machine. Fig. 2 is a rear view showing the arrangement of an air conditioning unit according to an embodiment of the present invention in a drum type washing and drying machine. Fig. 3 is a cross-sectional view showing an air-conditioning fan unit in which an air-conditioning unit according to an embodiment of the present invention is connected to a blower fan. Fig. 4 is a cross-sectional view showing a storage area of a compressor of an air conditioning unit according to an embodiment of the present invention and a rear side region which is a part of the air passage. Fig. 5 is a cross-sectional view showing a heat exchange region of an air conditioning unit according to an embodiment of the present invention. Fig. 6 is a plan view showing the air conditioning unit of the embodiment of the present invention with the dividing member on the unit casing removed. Fig. 7 is a perspective view of the air conditioning unit according to the embodiment of the present invention as seen from the oblique side in the state of Fig. 6. Fig. 8 is a perspective view showing the appearance of an air conditioning unit according to an embodiment of the present invention as seen from the front side. Fig. 9 is a plan view showing the exterior of the air conditioning unit according to the embodiment of the present invention from the upper portion. Fig. 10 is a plan view showing a dividing member under the unit casing of the air conditioning unit according to the embodiment of the present invention. Figure 11 is a perspective view of the divided member below the 10th figure. 29 201011138 Fig. 12 is a bottom view of the dividing member on the unit casing of the air conditioning unit according to the embodiment of the present invention. Fig. 13 is a perspective view showing a combined state of a compressor and an elastic seat provided in an air conditioning unit according to an embodiment of the present invention. Fig. 14 is a partial perspective view of the air conditioning unit according to the embodiment of the present invention as seen obliquely from the suction and discharge side in the state of Fig. 6. Fig. 15 is a side view of the air conditioning unit according to the embodiment of the present invention as seen from the side of the housing area. [Description of main components] 1...Drum type washing and drying machine 15d...Blowing part 2...Rotating drum 16...Circulating air introduction line 3...Sink 21...Condensed water tray 5...Circular air supply path 22...drain port 7...motor 23...separation water drain pan 8...through hole 24...frame portion 9...door 25...inclined portion 11."clothes entry and exit 26,43c,48...rib 12 ... water injection line 27... connected to 13... drain line 28, 29... partition wall 15 ... fan 28a, 29a... communication portion 15a... 31". evaporator 15b... screw Shaped case 32···Condenser 15c...sucking port 33...air supply line 15cl···connecting barrel 35.··filter 30 201011138
36··.過濾、室 37.·.壓縮機 37a...低溫配管 38···單元殼罩(空調殼罩) 39.. .空調風扇單元 41…連通部 41a...間隔壁 42…阻擔突起 43…彈性座體 43a".腳部 43b".蓋部 44…洗衣烘衣機本體 45,46,111...間隙 47…連通雜 51.. .開口 51a...引導溝 52,54·.·分隔壁 53a,53b...導件 56.. .遮蔽壁 56a...突出部 61.. .割線 62.. .連結部 63···貯存部 64.. .排水泵 65.. .排水管路 66.. .操作面板 67.. .控制基板 68.. .螺絲鎖固部 81.··空調風扇單元 101…閥機構(排水機構) 101a...排水口 101b...止回閥 101c...鉤部 101d...安裝子L 303al...熱交換區域 381.. .上分割構件 381a...接合凸緣 382.. .下分割構件 382a...接合凸緣 383.·.割線 384.. .密封材 386.. .劃分部 386a...上劃分壁 386b...下劃分壁 391.. .吸引導入口 392.. .吸引排出口 31 201011138 392a…凸緣壁 394a...凹部 392b...縱向直線緣 394b...第2凹部 392c...橫向直線緣 394c...底部 393…通風路徑 395....熱交換部 393a...熱交換區域 395a...吸入面 393al...熱交換部承載盤 395b...排出面 393b...—端側後部區域 395c·.·散熱片 393c...縱向彎曲區域 396·· •積水部 393cl…起伏形狀部 A...方向 393d...後部朝上擴張區域 S...空間 394...收容區域 鬱 3236··. Filtration, chamber 37. Compressor 37a... Low temperature piping 38···Unit housing cover (air conditioning cover) 39.. Air conditioning fan unit 41...communication unit 41a...partition wall 42... The resisting projections 43...the elastic seat 43a".the foot 43b".the cover 44...the washing and drying machine body 45,46,111...the gap 47...the connection 51.. the opening 51a...the guiding groove 52 , 54··· partition wall 53a, 53b... guide 56.. shielding wall 56a... protruding portion 61.. secant line 62.. connection portion 63··· storage portion 64.. 65.. .Drainage line 66.. Operation panel 67.. Control board 68.. Screw locking part 81. · Air conditioning fan unit 101... Valve mechanism (drainage mechanism) 101a... Drain port 101b. .. check valve 101c...hook portion 101d...mounter L 303al...heat exchange area 381.. upper split member 381a...joint flange 382.. lower split member 382a... Engagement flange 383.. secant line 384... sealing material 386.. partitioning portion 386a... upper partition wall 386b... lower partition wall 391.. suction inlet port 392.. suction suction port 31 201011138 392a... flange wall 394a... recess 392b... longitudinal straight edge 394b... second recess 392c... lateral straight edge 394c... bottom 393... ventilation path 395.... heat exchange portion 393a... heat exchange region 395a... suction surface 393al... heat exchange portion carrier tray 395b... discharge surface 393b... End side rear area 395c·. Heat sink 393c... Longitudinal bending area 396·· • Water accumulation part 393cl...undulating shape part A...direction 393d... Rearwardly upwardly expanding area S...Space 394.. Containment area Yu 32